AUTHOR=Subramanian Aneesh C. , Balmaseda Magdalena A. , Centurioni Luca , Chattopadhyay Rajib , Cornuelle Bruce D. , DeMott Charlotte , Flatau Maria , Fujii Yosuke , Giglio Donata , Gille Sarah T. , Hamill Thomas M. , Hendon Harry , Hoteit Ibrahim , Kumar Arun , Lee Jae-Hak , Lucas Andrew J. , Mahadevan Amala , Matsueda Mio , Nam SungHyun , Paturi Shastri , Penny Stephen G. , Rydbeck Adam , Sun Rui , Takaya Yuhei , Tandon Amit , Todd Robert E. , Vitart Frederic , Yuan Dongliang , Zhang Chidong TITLE=Ocean Observations to Improve Our Understanding, Modeling, and Forecasting of Subseasonal-to-Seasonal Variability JOURNAL=Frontiers in Marine Science VOLUME=6 YEAR=2019 URL=https://www.frontiersin.org/journals/marine-science/articles/10.3389/fmars.2019.00427 DOI=10.3389/fmars.2019.00427 ISSN=2296-7745 ABSTRACT=

Subseasonal-to-seasonal (S2S) forecasts have the potential to provide advance information about weather and climate events. The high heat capacity of water means that the subsurface ocean stores and re-releases heat (and other properties) and is an important source of information for S2S forecasts. However, the subsurface ocean is challenging to observe, because it cannot be measured by satellite. Subsurface ocean observing systems relevant for understanding, modeling, and forecasting on S2S timescales will continue to evolve with the improvement in technological capabilities. The community must focus on designing and implementing low-cost, high-value surface and subsurface ocean observations, and developing forecasting system capable of extracting their observation potential in forecast applications. S2S forecasts will benefit significantly from higher spatio-temporal resolution data in regions that are sources of predictability on these timescales (coastal, tropical, and polar regions). While ENSO has been a driving force for the design of the current observing system, the subseasonal time scales present new observational requirements. Advanced observation technologies such as autonomous surface and subsurface profiling devices as well as satellites that observe the ocean-atmosphere interface simultaneously can lead to breakthroughs in coupled data assimilation (CDA) and coupled initialization for S2S forecasts. These observational platforms should also be tested and evaluated in ocean observation sensitivity experiments with current and future generation CDA and S2S prediction systems. Investments in the new ocean observations as well as model and DA system developments can lead to substantial returns on cost savings from disaster mitigation as well as socio–economic decisions that use S2S forecast information.