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Auteurs principaux: Kar, Subhajit, Barkan, Roy, Taylor, John R.
Format: Preprint
Publié: 2025
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Accès en ligne:https://arxiv.org/abs/2507.13304
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author Kar, Subhajit
Barkan, Roy
Taylor, John R.
author_facet Kar, Subhajit
Barkan, Roy
Taylor, John R.
contents Submesoscale currents in the ocean's mixed layer (ML), consisting of fronts, eddies, and filaments, are characterized by order one Rossby (Ro) and Richardson (Ri) numbers. These currents play a crucial role in mediating vertical exchange between the surface and ocean interior and in facilitating cross-scale energy transfers. Despite a growing understanding of their generation mechanisms and energy pathways, two fundamental questions remain unresolved - how does a finite Ro modify the dynamics of ML instabilities, and what mechanisms are responsible for ML frontal arrest when Ro is order one. In this study, we address these questions through a linear stability analysis of a two-dimensional, geostrophically adjusted oceanic front based on the analytical model of Ou(1984), which allows systematic exploration across a range of Ro. In the low Ro, order one Ri regime, the most unstable mode is that of baroclinic instability, with the buoyancy flux serving as the primary source of perturbation kinetic energy. As Ro increases, the dominant instability becomes an inertia-critical layer type, characterized by a resonant interaction between a Rossby wave and an inertia-gravity wave. In the order one Ro regime, the shear production terms become comparable to the buoyancy flux term and even dominate in the region where the adjusted front is strongest. Our results suggest that shear production should be included in parameterizations of ML instabilities.minate in the region where the adjusted front is strongest. Our results suggest that shear production should be included in parameterizations of ML instabilities.
format Preprint
id arxiv_https___arxiv_org_abs_2507_13304
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Linear stability of an oceanic front at finite Rossby number
Kar, Subhajit
Barkan, Roy
Taylor, John R.
Atmospheric and Oceanic Physics
Submesoscale currents in the ocean's mixed layer (ML), consisting of fronts, eddies, and filaments, are characterized by order one Rossby (Ro) and Richardson (Ri) numbers. These currents play a crucial role in mediating vertical exchange between the surface and ocean interior and in facilitating cross-scale energy transfers. Despite a growing understanding of their generation mechanisms and energy pathways, two fundamental questions remain unresolved - how does a finite Ro modify the dynamics of ML instabilities, and what mechanisms are responsible for ML frontal arrest when Ro is order one. In this study, we address these questions through a linear stability analysis of a two-dimensional, geostrophically adjusted oceanic front based on the analytical model of Ou(1984), which allows systematic exploration across a range of Ro. In the low Ro, order one Ri regime, the most unstable mode is that of baroclinic instability, with the buoyancy flux serving as the primary source of perturbation kinetic energy. As Ro increases, the dominant instability becomes an inertia-critical layer type, characterized by a resonant interaction between a Rossby wave and an inertia-gravity wave. In the order one Ro regime, the shear production terms become comparable to the buoyancy flux term and even dominate in the region where the adjusted front is strongest. Our results suggest that shear production should be included in parameterizations of ML instabilities.minate in the region where the adjusted front is strongest. Our results suggest that shear production should be included in parameterizations of ML instabilities.
title Linear stability of an oceanic front at finite Rossby number
topic Atmospheric and Oceanic Physics
url https://arxiv.org/abs/2507.13304