Frontiers in Marine Science (Aug 2019)

Observational Needs of Sea Surface Temperature

  • Anne G. O’Carroll,
  • Edward M. Armstrong,
  • Helen M. Beggs,
  • Marouan Bouali,
  • Kenneth S. Casey,
  • Gary K. Corlett,
  • Prasanjit Dash,
  • Craig J. Donlon,
  • Chelle L. Gentemann,
  • Jacob L. Høyer,
  • Alexander Ignatov,
  • Kamila Kabobah,
  • Misako Kachi,
  • Yukio Kurihara,
  • Ioanna Karagali,
  • Eileen Maturi,
  • Christopher J. Merchant,
  • Salvatore Marullo,
  • Peter J. Minnett,
  • Matthew Pennybacker,
  • Balaji Ramakrishnan,
  • RAAJ Ramsankaran,
  • Rosalia Santoleri,
  • Swathy Sunder,
  • Stéphane Saux Picart,
  • Jorge Vázquez-Cuervo,
  • Werenfrid Wimmer

DOI
https://doi.org/10.3389/fmars.2019.00420
Journal volume & issue
Vol. 6

Abstract

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Sea surface temperature (SST) is a fundamental physical variable for understanding, quantifying and predicting complex interactions between the ocean and the atmosphere. Such processes determine how heat from the sun is redistributed across the global oceans, directly impacting large- and small-scale weather and climate patterns. The provision of daily maps of global SST for operational systems, climate modeling and the broader scientific community is now a mature and sustained service coordinated by the Group for High Resolution Sea Surface Temperature (GHRSST) and the CEOS SST Virtual Constellation (CEOS SST-VC). Data streams are shared, indexed, processed, quality controlled, analyzed, and documented within a Regional/Global Task Sharing (R/GTS) framework, which is implemented internationally in a distributed manner. Products rely on a combination of low-Earth orbit infrared and microwave satellite imagery, geostationary orbit infrared satellite imagery, and in situ data from moored and drifting buoys, Argo floats, and a suite of independent, fully characterized and traceable in situ measurements for product validation (Fiducial Reference Measurements, FRM). Research and development continues to tackle problems such as instrument calibration, algorithm development, diurnal variability, derivation of high-quality skin and depth temperatures, and areas of specific interest such as the high latitudes and coastal areas. In this white paper, we review progress versus the challenges we set out 10 years ago in a previous paper, highlight remaining and new research and development challenges for the next 10 years (such as the need for sustained continuity of passive microwave SST using a 6.9 GHz channel), and conclude with needs to achieve an integrated global high-resolution SST observing system, with focus on satellite observations exploited in conjunction with in situ SSTs. The paper directly relates to the theme of Data Information Systems and also contributes to Ocean Observing Governance and Ocean Technology and Networks within the OceanObs2019 objectives. Applications of SST contribute to all the seven societal benefits, covering Discovery; Ecosystem Health & Biodiversity; Climate Variability & Change; Water, Food, & Energy Security; Pollution & Human Health; Hazards and Maritime Safety; and the Blue Economy.

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