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salinity.bib
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salinity.bib
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@article{lueck_thermal_1990,
title = {Thermal {Inertia} of {Conductivity} {Cells}: {Observations} with a {Sea}-{Bird} {Cell}},
volume = {7},
doi = {10.1175/1520-0426(1990)007<0756:TIOCCO>2.0.CO;2},
abstract = {Abstract We have examined the magnitude and relaxation time of the thermal anomaly of the fluid flowing through the conductivity cell manufactured by Sea-Bird Electronics (SBE) that is induced by the heat stored in the wall of this cell using oceanic data collected in a thermohaline staircase. The relaxation is 9 to 10 s, about twice the value predicted by Lueck, while the initial magnitude of the conductivity error is 2.8\%, about 35\% smaller than predicted. The error in the measured conductivity is significant and long-lived and results in density errors detectable for 45 s after the sensor enters an isopycnal layer. An efficient numerical algorithm removes the anomaly from the measured conductivity signal and clears the resulting error from the computed salinity and density.},
number = {5},
journal = {Journal of Atmospheric and Oceanic Technology},
author = {Lueck, Rolf G. and Picklo, James J.},
year = {1990},
pages = {756--768},
}
@article{garau_thermal_2011,
title = {Thermal {Lag} {Correction} on {Slocum} {CTD} {Glider} {Data}},
volume = {28},
doi = {10.1175/JTECH-D-10-05030.1},
abstract = {AbstractIn this work a new methodology is proposed to correct the thermal lag error in data from unpumped CTD sensors installed on Slocum gliders. The advantage of the new approach is twofold: first, it takes into account the variable speed of the glider; and second, it can be applied to CTD profiles from an autonomous platform either with or without a reference cast. The proposed methodology finds values for four correction parameters that minimize the area between two temperature–salinity curves given by two CTD profiles. A field experiment with a Slocum glider and a standard CTD was conducted to test the method. Thermal lag–induced salinity error of about 0.3 psu was found and successfully corrected.},
number = {9},
journal = {Journal of Atmospheric and Oceanic Technology},
author = {Garau, Bartolomé and Ruiz, Simón and Zhang, Weifeng G. and Pascual, Ananda and Heslop, Emma and Kerfoot, John and Tintoré, Joaquín},
year = {2011},
pages = {1065--1071},
}
@article{giddy_stirring_2021,
title = {Stirring of {Sea}‐{Ice} {Meltwater} {Enhances} {Submesoscale} {Fronts} in the {Southern} {Ocean}},
volume = {126},
issn = {2169-9275, 2169-9291},
doi = {10.1029/2020JC016814},
language = {en},
number = {4},
journal = {Journal of Geophysical Research: Oceans},
author = {Giddy, I. and Swart, S. and du Plessis, M. and Thompson, A. F. and Nicholson, S.‐A.},
year = {2021},
file = {Full Text:/Users/XNUNEI/Zotero/storage/MMK35G2T/Giddy et al. - 2021 - Stirring of Sea‐Ice Meltwater Enhances Submesoscal.pdf:application/pdf},
}
@article{gregor_glidertools_2019,
title = {{GliderTools}: {A} {Python} {Toolbox} for {Processing} {Underwater} {Glider} {Data}},
volume = {6},
issn = {2296-7745},
shorttitle = {{GliderTools}},
doi = {10.3389/fmars.2019.00738},
journal = {Frontiers in Marine Science},
author = {Gregor, Luke and Ryan-Keogh, Thomas J. and Nicholson, Sarah-Anne and du Plessis, Marcel and Giddy, Isabelle and Swart, Sebastiaan},
year = {2019},
pages = {738},
file = {Full Text:/Users/XNUNEI/Zotero/storage/794KNCJP/Gregor et al. - 2019 - GliderTools A Python Toolbox for Processing Under.pdf:application/pdf},
}
@article{fer_microstructure_2014,
title = {Microstructure {Measurements} from an {Underwater} {Glider} in the {Turbulent} {Faroe} {Bank} {Channel} {Overflow}},
volume = {31},
issn = {0739-0572, 1520-0426},
url = {https://journals.ametsoc.org/view/journals/atot/31/5/jtech-d-13-00221_1.xml},
doi = {10.1175/JTECH-D-13-00221.1},
number = {5},
journal = {Journal of Atmospheric and Oceanic Technology},
author = {Fer, Ilker and Peterson, Algot K. and Ullgren, Jenny E.},
year = {2014},
pages = {1128--1150},
file = {Full Text:/Users/XNUNEI/Zotero/storage/YGW4VF52/Fer et al. - 2014 - Microstructure Measurements from an Underwater Gli.pdf:application/pdf},
}
@inproceedings{janzen_physical_2011,
address = {Waikoloa, HI},
title = {Physical oceanographic data from {Seaglider} trials in stratified coastal waters using a new pumped payload {CTD}},
isbn = {978-1-4577-1427-6 978-0-933957-39-8},
url = {http://ieeexplore.ieee.org/document/6107290/},
doi = {10.23919/OCEANS.2011.6107290},
booktitle = {{OCEANS}'11 {MTS}/{IEEE} {KONA}},
publisher = {IEEE},
author = {Janzen, Carol D. and Creed, Elizabeth L.},
year = {2011},
pages = {1--7},
}
@article{woo_delayed_2021,
title = {Delayed {Mode} {QA}/{QC} {Best} {Practice} {Manual} {Version} 3.0 {Integrated} {Marine} {Observing} {System}.},
url = {https://catalogue-imos.aodn.org.au:443/geonetwork/srv/api/records/b82ec5c4-3b6a-4a39-a4e7-f1adba2d5372},
doi = {10.26198/5C997B5FDC9BD},
journal = {Australian Ocean Data Network},
author = {Woo, L. Mun and Gourcuff, Claire},
year = {2021},
}
@article{morison_correction_1994,
title = {The {Correction} for {Thermal}-{Lag} {Effects} in {Sea}-{Bird} {CTD} {Data}},
volume = {11},
issn = {0739-0572, 1520-0426},
url = {http://journals.ametsoc.org/doi/10.1175/1520-0426(1994)011<1151:TCFTLE>2.0.CO;2},
doi = {10.1175/1520-0426(1994)011<1151:TCFTLE>2.0.CO;2},
language = {en},
number = {4},
journal = {Journal of Atmospheric and Oceanic Technology},
author = {Morison, James and Andersen, Roger and Larson, Nordeen and D'Asaro, Eric and Boyd, Tim},
year = {1994},
pages = {1151--1164},
}
@article{johnson_sensor_2007,
title = {Sensor {Corrections} for {Sea}-{Bird} {SBE}-{41CP} and {SBE}-41 {CTDs}},
volume = {24},
issn = {0739-0572, 1520-0426},
url = {https://journals.ametsoc.org/doi/10.1175/JTECH2016.1},
doi = {10.1175/JTECH2016.1},
abstract = {Sensor response corrections for two models of Sea-Bird Electronics, Inc., conductivity–temperature–depth (CTD) instruments (the SBE-41CP and SBE-41) designed for low-energy profiling applications were estimated and applied to oceanographic data. Three SBE-41CP CTDs mounted on prototype ice-tethered profilers deployed in the Arctic Ocean sampled diffusive thermohaline staircases and telemetered data to shore at their full 1-Hz resolution. Estimations of and corrections for finite thermistor time response, time shifts between when a parcel of water was sampled by the thermistor and when it was sampled by the conductivity cell, and the errors in salinity induced by the thermal inertia of the conductivity cell are developed with these data. In addition, thousands of profiles from Argo profiling floats equipped with SBE-41 CTDs were screened to select examples where thermally well-mixed surface layers overlaid strong thermoclines for which standard processing often yields spuriously fresh salinity estimates. Hundreds of profiles so identified are used to estimate and correct for the conductivity cell thermal mass error in SBE-41 CTDs.},
language = {en},
number = {6},
journal = {Journal of Atmospheric and Oceanic Technology},
author = {Johnson, Gregory C. and Toole, John M. and Larson, Nordeen G.},
year = {2007},
pages = {1117--1130},
file = {Full Text:/Users/XNUNEI/Zotero/storage/BSVVRCPY/Johnson et al. - 2007 - Sensor Corrections for Sea-Bird SBE-41CP and SBE-4.pdf:application/pdf},
}
@incollection{liu_glider_2015,
title = {Glider {Salinity} {Correction} for {Unpumped} {CTD} {Sensors} across a {Sharp} {Thermocline}},
isbn = {978-0-12-802022-7},
url = {https://linkinghub.elsevier.com/retrieve/pii/B9780128020227000171},
language = {en},
booktitle = {Coastal {Ocean} {Observing} {Systems}},
publisher = {Elsevier},
author = {Liu, Yonggang and Weisberg, Robert H. and Lembke, Chad},
year = {2015},
doi = {10.1016/B978-0-12-802022-7.00017-1},
pages = {305--325},
}
@misc{bennett_determining_2019,
title = {Determining {Seaglider} {Velocities} {Automatically}},
url = {http://hdl.handle.net/1773/44948},
publisher = {School of Oceanography, University of Washington},
author = {Bennett, James and Stahr, Fritz and Eriksen, Charlie},
year = {2019},
}
@article{owens_improved_2009,
title = {An improved calibration method for the drift of the conductivity sensor on autonomous {CTD} profiling floats by θ–{S} climatology},
volume = {56},
issn = {09670637},
url = {https://linkinghub.elsevier.com/retrieve/pii/S0967063708002021},
doi = {10.1016/j.dsr.2008.09.008},
language = {en},
number = {3},
journal = {Deep Sea Research Part I: Oceanographic Research Papers},
author = {Owens, W. Brechner and Wong, Annie P.S.},
year = {2009},
pages = {450--457},
}
@article{wong_delayed-mode_2003,
title = {Delayed-{Mode} {Calibration} of {Autonomous} {CTD} {Profiling} {Float} {Salinity} {Data} by \textit{θ} – \textit{{S}} {Climatology}*},
volume = {20},
issn = {0739-0572, 1520-0426},
url = {http://journals.ametsoc.org/doi/10.1175/1520-0426(2003)020<0308:DMCOAC>2.0.CO;2},
doi = {10.1175/1520-0426(2003)020<0308:DMCOAC>2.0.CO;2},
language = {en},
number = {2},
journal = {Journal of Atmospheric and Oceanic Technology},
author = {Wong, Annie P. S. and Johnson, Gregory C. and Owens, W. Brechner},
year = {2003},
pages = {308--318},
}
@article{allen_near-automatic_2020,
title = {Near-{Automatic} {Routine} {Field} {Calibration}/{Correction} of {Glider} {Salinity} {Data} {Using} {Whitespace} {Maximization} {Image} {Analysis} of {Theta}/{S} {Data}},
volume = {7},
issn = {2296-7745},
url = {https://www.frontiersin.org/article/10.3389/fmars.2020.00398/full},
doi = {10.3389/fmars.2020.00398},
journal = {Frontiers in Marine Science},
author = {Allen, John T. and Munoz, Cristian and Gardiner, Jim and Reeve, Krissy A. and Alou-Font, Eva and Zarokanellos, Nikolaos},
year = {2020},
pages = {398},
file = {Full Text:/Users/XNUNEI/Zotero/storage/W9XK4NNH/Allen et al. - 2020 - Near-Automatic Routine Field CalibrationCorrectio.pdf:application/pdf},
}
@article{bosse_spreading_2015,
title = {Spreading of {Levantine} {Intermediate} {Waters} by submesoscale coherent vortices in the northwestern {Mediterranean} {Sea} as observed with gliders},
volume = {120},
issn = {21699275},
url = {http://doi.wiley.com/10.1002/2014JC010263},
doi = {10.1002/2014JC010263},
language = {en},
number = {3},
journal = {Journal of Geophysical Research: Oceans},
author = {Bosse, Anthony and Testor, Pierre and Mortier, Laurent and Prieur, Louis and Taillandier, Vincent and d'Ortenzio, Fabrizio and Coppola, Laurent},
year = {2015},
pages = {1599--1622},
file = {Full Text:/Users/XNUNEI/Zotero/storage/9AZEC3FS/Bosse et al. - 2015 - Spreading of Levantine Intermediate Waters by subm.pdf:application/pdf},
}
@article{durack_fifty-year_2010,
title = {Fifty-{Year} {Trends} in {Global} {Ocean} {Salinities} and {Their} {Relationship} to {Broad}-{Scale} {Warming}},
volume = {23},
issn = {1520-0442, 0894-8755},
url = {http://journals.ametsoc.org/doi/10.1175/2010JCLI3377.1},
doi = {10.1175/2010JCLI3377.1},
abstract = {Abstract
Using over 1.6 million profiles of salinity, potential temperature, and neutral density from historical archives and the international Argo Program, this study develops the three-dimensional field of multidecadal linear change for ocean-state properties. The period of analysis extends from 1950 to 2008, taking care to minimize the aliasing associated with the seasonal and major global El Niño–Southern Oscillation modes. Large, robust, and spatially coherent multidecadal linear trends in salinity to 2000-dbar depth are found. Salinity increases at the sea surface are found in evaporation-dominated regions and freshening in precipitation-dominated regions, with the spatial pattern of change strongly resembling that of the mean salinity field, consistent with an amplification of the global hydrological cycle. Subsurface salinity changes on pressure surfaces are attributable to both isopycnal heave and real water-mass modification of the temperature–salinity relationship. Subduction and circulation by the ocean’s mean flow of surface salinity and temperature anomalies appear to account for most regional subsurface salinity changes on isopycnals. Broad-scale surface warming and the associated poleward migration of isopycnal outcrops drive a clear and repeating pattern of subsurface isopycnal salinity change in each independent ocean basin. Qualitatively, the observed global multidecadal salinity changes are thus consonant with both broad-scale surface warming and the amplification of the global hydrological cycle.},
language = {en},
number = {16},
journal = {Journal of Climate},
author = {Durack, Paul J. and Wijffels, Susan E.},
year = {2010},
pages = {4342--4362},
}