Coupled Ocean–Atmosphere Offshore Decay Scale of Cold SST Signals along Upwelling Eastern Boundaries

A simple analytic model is developed to represent the offshore decay of cold sea surface temperature (SST) signals that originate from wind-driven upwelling at a coastal boundary. The model couples an oceanic mixed layer to an atmospheric boundary layer through wind stress and air–sea heat exchange....

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Bibliographic Details
Published in:Journal of climate 2016-12, Vol.29 (23), p.8317-8331
Main Authors: Spall, Michael A., Schneider, Niklas
Format: Article
Language:English
Subjects:
Advection
Air-sea flux
Atmosphere
Atmospheric boundary layer
Atmospheric models
Balances (scales)
Baroclinic instability
Boundary layer stability
Boundary layer temperatures
Boundary layers
Budgets
Climatology
Coasts
Cold
Decay
ENVIRONMENTAL SCIENCES
Feedback
Heat
Heat exchange
Heat flux
Heat transfer
Instability
Length
Marine
Meteorology & Atmospheric Sciences
Mixed layer
Ocean circulation
Ocean mixed layer
Ocean models
Ocean-atmosphere system
Offshore
Physics
Sea surface
Sea surface temperature
Surface temperature
Surface wind
Systems analysis
Temperature
Temperature effects
Three dimensional models
Topography
Two dimensional models
Upwelling
Velocity
Vortices
Weather
Wind
Wind stress
Wind-driven upwelling
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Description
Summary:A simple analytic model is developed to represent the offshore decay of cold sea surface temperature (SST) signals that originate from wind-driven upwelling at a coastal boundary. The model couples an oceanic mixed layer to an atmospheric boundary layer through wind stress and air–sea heat exchange. The primary mechanism that controls SST is a balance between Ekman advection and air–sea exchange. The offshore penetration of the cold SST signal decays exponentially with a length scale that is the product of the ocean Ekman velocity and a time scale derived from the air–sea heat flux and the radiative balance in the atmospheric boundary layer. This cold SST signal imprints on the atmosphere in terms of both the boundary layer temperature and surface wind. Nonlinearities due to the feedback between SST and atmospheric wind, baroclinic instability, and thermal wind in the atmospheric boundary layer all slightly modify this linear theory. The decay scales diagnosed from two-dimensional and three-dimensional eddy-resolving numerical ocean models are in close agreement with the theory, demonstrating that the basic physics represented by the theory remain dominant even in these more complete systems. Analysis of climatological SST off the west coast of the United States also shows a decay of the cold SST anomaly with scale roughly in agreement with the theory.
ISSN:0894-8755
1520-0442
DOI:10.1175/JCLI-D-16-0109.1