Modeling the Near‐Surface Diurnal Cycle of Sea Surface Temperature in the Mediterranean Sea

The diurnal cycle of sea surface temperature (SST) is an important component of the ocean‐atmosphere system and is necessary for accurately computing air‐sea heat fluxes. Ocean temperatures in the near‐surface are highly sensitive to atmospheric conditions and can vary significantly depending on tim...

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Bibliographic Details
Published in:Journal of geophysical research. Oceans 2019-01, Vol.124 (1), p.171-183
Main Authors: Pimentel, S., Tse, W.‐H., Xu, H., Denaxa, D., Jansen, E., Korres, G., Mirouze, I., Storto, A.
Format: Article
Language:English
Subjects:
Air-sea flux
Atmosphere
Atmospheric conditions
Atmospheric models
Climate
Climate models
Climate system
Computation
Computer applications
Diurnal cycle
diurnal variability
Diurnal variations
Energy transfer
General circulation models
Geophysics
Gliders
Heat exchange
Heat flux
Heat transfer
Instruments
Mathematical models
Model testing
modeling
Modelling
Mooring
Ocean models
Ocean temperature
Oceans
Records
Remote sensing
Satellite instruments
Satellite-borne instruments
Satellites
Sea surface
Sea surface temperature
SEVIRI
Skin temperature
Surface boundary layer
Surface layers
Surface structure
Surface temperature
Temperature
Temperature effects
Time of use
Variability
Vertical profiles
Weather forecasting
Well construction
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Summary:The diurnal cycle of sea surface temperature (SST) is an important component of the ocean‐atmosphere system and is necessary for accurately computing air‐sea heat fluxes. Ocean temperatures in the near‐surface are highly sensitive to atmospheric conditions and can vary significantly depending on time of day. Ocean general circulation models are unable to fully capture the near‐surface diurnal SST variability, because they do not possess the necessary vertical structure and resolution. Furthermore, SST observations come from a number of sources that represent the temperature at various near‐surface depths. This presents difficulties when assimilating SST observations as well as constructing robust climate records of SST. In this study we model the fine‐scale near‐surface structure allowing SST comparisons between foundation SST, SST at depth, subskin SST, and skin SST. Hourly model results, forced and initialized using readily available reanalysis data, are from a 2‐year period, 2013–2014, over the Mediterranean Sea. Various solar absorption parameterizations are examined, and the resulting SSTs are compared to Spinning Enhanced Visible and InfraRed Imager‐derived observations of the skin temperature. Plain Language Summary The sea surface temperature (SST) is an important variable of the climate system. It governs the exchange of energy between the ocean and atmosphere. Accurate knowledge of SST is essential for weather and ocean forecasting. The vast majority of our observations of SST are remotely sensed and derived from satellite instruments that record the temperature within the top 1 mm. These observations are complemented by a mixture of ocean moorings and gliders that measure the temperature at various near‐surface depths (∼20 cm to 1 m). SSTs are highly sensitive to atmospheric conditions and can vary significantly depending on time of day and near‐surface depth. This presents difficulties when combining different observations to construct robust climate records of SST. In addition, large‐scale computational models of the ocean typically resolve temperature in a surface layer ∼1 m thick and are unable to fully capture SST variability. It is therefore challenging to properly compare and/or merge modeled SSTs with observed SSTs. To address these challenges, we present a computational model of the fine‐scale near‐surface ocean structure. The model is tested in the Mediterranean Sea and used to produce a 2‐year data set that makes possible SST comparis
ISSN:2169-9275
2169-9291
DOI:10.1029/2018JC014289