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Air-Sea interaction over the Gulf Stream in an ensemble of HighResMIP present climate simulations.

Authors :
Bellucci, Alessio
Athanasiadis, P. J.
Scoccimarro, E.
Ruggieri, P.
Gualdi, S.
Fedele, G.
Haarsma, R. J.
Garcia-Serrano, J.
Castrillo, M.
Putrahasan, D.
Sanchez-Gomez, E.
Moine, M.-P.
Roberts, C. D.
Roberts, M. J.
Seddon, J.
Vidale, P. L.
Source :
Climate Dynamics; Apr2021, Vol. 56 Issue 7/8, p2093-2111, 19p
Publication Year :
2021

Abstract

A dominant paradigm for mid-latitude air-sea interaction identifies the synoptic-scale atmospheric "noise" as the main driver for the observed ocean surface variability. While this conceptual model successfully holds over most of the mid-latitude ocean surface, its soundness over frontal zones (including western boundary currents; WBC) characterized by intense mesoscale activity, has been questioned in a number of studies suggesting a driving role for the small scale ocean dynamics (mesoscale oceanic eddies) in the modulation of air-sea interaction. In this context, climate models provide a powerful experimental device to inspect the emerging scale-dependent nature of mid-latitude air-sea interaction. This study assesses the impact of model resolution on the representation of air-sea interaction over the Gulf Stream region, in a multi-model ensemble of present-climate simulations performed using a common experimental design. Lead-lag correlation and covariance patterns between sea surface temperature (SST) and turbulent heat flux (THF) are diagnosed to identify the leading regimes of air-sea interaction in a region encompassing both the Gulf Stream system and the North Atlantic subtropical basin. Based on these statistical metrics it is found that coupled models based on "laminar" (eddy-parameterised) and eddy-permitting oceans are able to discriminate between an ocean-driven regime, dominating the region controlled by the Gulf Stream dynamics, and an atmosphere-driven regime, typical of the open ocean regions. However, the increase of model resolution leads to a better representation of SST and THF cross-covariance patterns and functional forms, and the major improvements can be largely ascribed to a refinement of the oceanic model component. [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
09307575
Volume :
56
Issue :
7/8
Database :
Complementary Index
Journal :
Climate Dynamics
Publication Type :
Academic Journal
Accession number :
149990140
Full Text :
https://doi.org/10.1007/s00382-020-05573-z