The role of surface fluxes in OGCM using satellite SST. Validation of and sensitivity to the forcing frequency of the Mediterranean thermohaline circulation

In this article we study the effect of high frequency surface momentum and heat fluxes in the numerical simulation of some key ocean processes of the Mediterranean thermohaline circulation. The lack of synoptic and reliable heat and freshwater flux datasets is bypassed using the relaxation approach both for the salinity and temperature surface field. We propose a parameterization of the heat fluxes in which the temperature restoring coefficient depends on wind intensity and regime and that requires the use of simuoultaneous satellite daily SST estimates as restoring field. The consistency of the proposed parameterization and of its numerical implementation with the previous oceanic boundary layer studies has been verified trough the analysis of the Saunders’ proportionality constant. This parameterization coupling simultaneous surface heat fluxes and wind trough the skin-bulk temperature difference, recovers the high variability of the air-sea exchanges of the extreme events in the Mediterranean sea. The effect of high frequency surface momentum and heat fluxes is studied comparing results from two different experiments forced with monthly and daily surface wind and satellite SST data sets. This comparisons show the relevance of high frequency forcing in the representation of the dynamical processes relative to the intermediate water mass transformation and horizontal advection as well as in the deep water formation in the north-western Mediterranean Sea.