Abstract
Abstract. The role played by wind-forced anticyclones in the vertical transport and mixing at the ocean mesoscale is investigated with a primitive-equation numerical model in an idealized configuration. The focus of this work is to determine how the stratification impacts such transport. The flows, forced only at the surface by an idealized wind forcing, are predominantly horizontal and, on average, quasigeostrophic. Inside vortex cores and intense filaments, however, the dynamics is strongly ageostrophic. Mesoscale anticyclones appear as "islands" of increased penetration of wind energy into the ocean interior and they represent the maxima of available potential energy. The amount of available potential energy is directly correlated with the degree of stratification. The wind energy injected at the surface is transferred at depth through the generation and subsequent straining effect of Vortex Rossby Waves (VRWs), and through near-inertial internal oscillations trapped inside anticyclonic vortices. Both these mechanisms are affected by stratification. Stronger transfer but larger confinement close to the surface is found when the stratification is stronger. For weaker stratification, vertical mixing close to the surface is less intense but below about 150 m attains substantially higher values due to an increased contribution of both VRWs, whose time scale is on the order of few days, and of near-inertial motions, with a time scale of few hours.
Highlights
The ocean circulation is characterized by a surface wind driven component, a stable stratification below the first few hundred meters of the water column, a meridional over-turning circulation and turbulent motions
A fraction of this input feeds into the large-scale general circulation, partly removed by baroclinic instability whereby the mesoscale flow structures arise
Recent works point to mesoscale vortices as responsible for transferring wind energy into the ocean interior through near inertial oscillations (Kunze, 1985; Klein et al, 2004; Danioux et al, 2008)
Summary
The ocean circulation is characterized by a surface wind driven component, a stable stratification below the first few hundred meters of the water column, a meridional over-. The vertical structure of mesoscale vortices and the associated mixing, had long been viewed and parameterized in a simplified manner (Gent and McWilliams, 1995; Griffies, 2000) until recent findings have highlighted their role in transferring wind-forced near-inertial oscillations into the ocean interior (Kunze, 1985; Klein et al, 2004; Danioux et al, 2008). In this respect eddies constitute a different pathway by which inertial energy can reach the ocean interior and their contribution to vertical mixing may be fundamental in maintaining the meridional overturning circulation. We study the transfer of the wind energy into the underlying flow and its redistribution in the fluid column, focusing on the vertical transport properties of the mesoscale vortices
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