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	Provedor de dados ArchiMer (2) Autor Ardhuin, Fanny (1) Ashton, Ian (1) Bellerby, Richard G.j. (1) Bhadury, Punyasloke (1) Chapron, Bertrand (1) Findlay, Helen S. (1) Forster, Rodney (1) Gernez, Pierre (1) Grouazel, Antoine (1) Holding, Thomas (1) Land, Peter E. (1) Palmer, Stephanie C. J. (1) Piolle, Jean-francois (1) Quilfen, Yves (1) Reul, Nicolas (1) Sabia, Roberto (1) Salisbury, Joseph (1) Shutler, Jamie D. (1) Thomas, Yoann (1) Vandemark, Douglas (1) Mais... Palavra-chave Earth observation (2) Aquarius (1) CORA (1) Carbonate chemistry (1) Dissolved inorganic carbon (1) Ecological modeling (1) Fish (1) HAB risk assessment (1) HadGEM2-ES (1) Kelp (1) Ocean acidification (1) Production monitoring (1) SMOS (1) Shellfish (1) Site selection (1) Total alkalinity (1) Mais... Tipo do documento Text (2) Ano 2021 (1) 2019 (1) País France (2) Idioma Inglês (2)		Registro completo Provedor de dados:  ArchiMer País:  France Título:  Optimum satellite remote sensing of the marine carbonate system using empirical algorithms in the global ocean, the Greater Caribbean, the Amazon Plume and the Bay of Bengal Autores:  Land, Peter E. Findlay, Helen S. Shutler, Jamie D. Ashton, Ian Holding, Thomas Grouazel, Antoine Ardhuin, Fanny Reul, Nicolas Piolle, Jean-francois Chapron, Bertrand Quilfen, Yves Bellerby, Richard G.j. Bhadury, Punyasloke Salisbury, Joseph Vandemark, Douglas Sabia, Roberto Data:  2019-12 Ano:  2019 Palavras-chave:  Carbonate chemistry Earth observation Ocean acidification Total alkalinity Dissolved inorganic carbon SMOS Aquarius CORA HadGEM2-ES Resumo:  Improving our ability to monitor ocean carbonate chemistry has become a priority as the ocean continues to absorb carbon dioxide from the atmosphere. This long-term uptake is reducing the ocean pH; a process commonly known as ocean acidification. The use of satellite Earth Observation has not yet been thoroughly explored as an option for routinely observing surface ocean carbonate chemistry, although its potential has been highlighted. We demonstrate the suitability of using empirical algorithms to calculate total alkalinity (AT) and total dissolved inorganic carbon (CT), assessing the relative performance of satellite, interpolated in situ, and climatology datasets in reproducing the wider spatial patterns of these two variables. Both AT and CT in situ data are reproducible, both regionally and globally, using salinity and temperature datasets, with satellite observed salinity from Aquarius and SMOS providing performance comparable to other datasets for the majority of case studies. Global root mean squared difference (RMSD) between in situ validation data and satellite estimates is 17 μmol kg−1 with bias  < 5 μmol kg−1 for AT and 30 μmol kg−1 with bias  < 10 μmol kg−1 for CT. This analysis demonstrates that satellite sensors provide a credible solution for monitoring surface synoptic scale AT and CT. It also enables the first demonstration of observation-based synoptic scale AT and CT temporal mixing in the Amazon plume for 2010–2016, complete with a robust estimation of their uncertainty. Tipo:  Text Idioma:  Inglês Identificador:  https://archimer.ifremer.fr/doc/00591/70267/68368.pdf DOI:10.1016/j.rse.2019.111469 https://archimer.ifremer.fr/doc/00591/70267/ Editor:  Elsevier BV Formato:  application/pdf Fonte:  Remote Sensing Of Environment (0034-4257) (Elsevier BV), 2019-12 , Vol. 235 , P. 111469 (15p.) Direitos:  info:eu-repo/semantics/openAccess restricted use Fechar

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