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Get Free AccessEarth and Space Science Open Archive This preprint has been submitted to and is under consideration at Geophysical Research Letters. ESSOAr is a venue for early communication or feedback before peer review. Data may be preliminary.Learn more about preprints preprintOpen AccessYou are viewing the latest version by default [v1]Water Stress Explains the Aerodynamic versus Radiometric Surface Temperature Paradox in Thermal-based Evaporation ModelingAuthorsKaniskaMallickiDDennis DBaldocchiiDAndrew JamesJarvisTianHuIvonneTrebsiDMauroSulisNishanBhattaraiChristianBossungiDYomnaEidJamieCleverlyJasonBeringerWilliamWoodgateRichardSilbersteinNinaHinko-NajeraWayne StewartMeyerDarrenGhentZoltanSzantoiGillesBouletWilliam P.KustasiDSee all authors Kaniska MallickiDCorresponding Author• Submitting AuthorLuxembourg Institute of Science and TechnologyiDhttps://orcid.org/0000-0002-2735-930Xview email addressThe email was not providedcopy email addressDennis D BaldocchiiDUniversity of California, BerkeleyiDhttps://orcid.org/0000-0003-3496-4919view email addressThe email was not providedcopy email addressAndrew James JarvisLancaster Universityview email addressThe email was not providedcopy email addressTian HuLuxembourg Institute of Science and Technologyview email addressThe email was not providedcopy email addressIvonne TrebsiDLuxembourg Institute of Science and Technology (LIST)iDhttps://orcid.org/0000-0001-5966-4942view email addressThe email was not providedcopy email addressMauro SulisLuxembourg Institute of Science and Technologyview email addressThe email was not providedcopy email addressNishan BhattaraiUnited States Department of Agricultureview email addressThe email was not providedcopy email addressChristian BossungiDLuxembourg Institute of Science and TechnologyiDhttps://orcid.org/0000-0003-4651-2645view email addressThe email was not providedcopy email addressYomna EidThe Julius Maximilians University of Würzburgview email addressThe email was not providedcopy email addressJamie CleverlyJames Cook Universityview email addressThe email was not providedcopy email addressJason BeringerUniversity of Western Australiaview email addressThe email was not providedcopy email addressWilliam WoodgateThe University of Queenslandview email addressThe email was not providedcopy email addressRichard SilbersteinEdith Cowan Universityview email addressThe email was not providedcopy email addressNina Hinko-NajeraUniversity of Melbourneview email addressThe email was not providedcopy email addressWayne Stewart MeyerUniversity of Adelaideview email addressThe email was not providedcopy email addressDarren GhentUniversity of Leicesterview email addressThe email was not providedcopy email addressZoltan SzantoiEuropean Space Agencyview email addressThe email was not providedcopy email addressGilles BouletCESBIO/IRD, Franceview email addressThe email was not providedcopy email addressWilliam P. KustasiDUSDA-ARSiDhttps://orcid.org/0000-0001-5727-4350view email addressThe email was not providedcopy email address
Kaniska Mallick, Dennis Baldocchi, Andrew Jarvis, Tian Hu, Ivonne Trebs, Mauro Sulis, Nishan Bhattarai, Christian Bossung, Yomna Eid, James Cleverly, Jason Beringer, William Woodgate, Richard Silberstein, Nina Hinko‐Najera, Wayne S. Meyer, Darren Ghent, Zoltan Szantoi, Gilles Boulet, William P. Kustas (2022). Water Stress Explains the Aerodynamic versus Radiometric Surface Temperature Paradox in Thermal-based Evaporation Modeling. , DOI: https://doi.org/10.1002/essoar.10511004.1.
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Type
Preprint
Year
2022
Authors
19
Datasets
0
Total Files
0
Language
en
DOI
https://doi.org/10.1002/essoar.10511004.1
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