The Universal Aspect Ratio of Vortices in Rotating Stratified Flows: Theory and Simulation

TL;DR

This paper derives a universal formula for the aspect ratio of vortices in rotating stratified flows, validated through extensive simulations, revealing key conditions for cyclone and anticyclone structures based on stratification and rotation parameters.

Contribution

It introduces a new, general relationship for vortex aspect ratio in rotating stratified fluids applicable to various vortex types and regimes, validated by numerical simulations.

Findings

Derived a universal aspect ratio relation for vortices in rotating stratified flows.

Validated the relation with diverse numerical simulations of Boussinesq vortices.

Showed significant deviations from the classical f/N conjecture in computed aspect ratios.

Abstract

We derive a relationship for the vortex aspect ratio $\alpha$ (vertical half-thickness over horizontal length scale) for steady and slowly evolving vortices in rotating stratified fluids, as a function of the Brunt-Vaisala frequencies within the vortex $N_c$ and in the background fluid outside the vortex $\bar{N}$, the Coriolis parameter $f$, and the Rossby number $Ro$ of the vortex: $\alpha^2 = Ro(1+Ro) f^2/(N_c^2-\bar{N}^2)$. This relation is valid for cyclones and anticyclones in either the cyclostrophic or geostrophic regimes; it works with vortices in Boussinesq fluids or ideal gases, and the background density gradient need not be uniform. Our relation for $\alpha$ has many consequences for equilibrium vortices in rotating stratified flows. For example, cyclones must have $N_c^2 > \bar{N}^2$; weak anticyclones (with $|Ro| < 1$) must have $N_c^2 < \bar{N}^2; and strong anticyclones must have $N_c^2 > \bar{N}^2$. We verify our relation for $\alpha$ with numerical simulations of the three-dimensional Boussinesq equations for a wide variety of vortices, including: vortices that are initially in (dissipationless) equilibrium and then evolve due to an imposed weak viscous dissipation or density radiation; anticyclones created by the geostrophic adjustment of a patch of locally mixed density; cyclones created by fluid suction from a small localised region; vortices created from the remnants of the violent breakups of columnar vortices; and weakly non-axisymmetric vortices. The values of the aspect ratios of our numerically-computed vortices validate our relationship for $\alpha$, and generally they differ significantly from the values obtained from the much-cited conjecture that $\alpha = f/\bar{N}$ in quasi-geostrophic vortices.