Non-linear evolution of the horizontal shear instability in stratified rotating fluids under the complete Coriolis acceleration

Abstract

This paper investigates the non-linear dynamics of horizontal shear instability in an incompressible, stratified and rotating fluid in the non-traditional f-plane, i.e. with the full Coriolis acceleration, using direct numerical simulations. The study is restricted to two-dimensional horizontal perturbations. It is therefore independent of the vertical (traditional) Coriolis parameter. However, the flow has three velocity components due to the horizontal (non-traditional) Coriolis parameter. Three different scenarios of non-linear evolution of the shear instability are identified, depending on the non-dimensional Brunt-V\"ais\"al\"a frequency N and the non-dimensional non-traditional Coriolis parameter f (non-dimensionalized by the maximum shear), in the range f<N for fixed Reynolds and Schmidt numbers Re=2000, Sc=1. When the stratification is strong N 1, the shear instability generates stable Kelvin-Helmholtz billows like in the traditional limit f=0. Furthermore, when N1, the governing equations for any f can be transformed into those for f=0. This enables us to directly predict the characteristics of the flow depending on f and N. When N is around unity and f is above a threshold, the primary Kelvin-Helmholtz vortex is destabilised by secondary instabilities but it remains coherent. For weaker stratification, N≤slant0.5 and f large enough, secondary instabilities develop vigorously and destroy the primary vortex into small-scales turbulence. Concomitantly, the enstrophy rises to high values by stretching/tilting as in fully three-dimensional flows. A local analysis of the flow prior to the onset of secondary instabilities reveals that the Fjortoft necessary condition for instability is satisfied, suggesting that they correspond to shear instabilities.

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