The Universal Aspect Ratio of Vortices in Rotating Stratifi?ed Flows: Experiments and Observations

TL;DR

This paper introduces and validates a universal law for the aspect ratio of vortices in rotating stratified flows, applicable to laboratory experiments and natural phenomena like meddies and Jupiter's storms.

Contribution

The paper derives and experimentally confirms a new law relating vortex aspect ratio to flow parameters, extending understanding of vortex structure in rotating stratified fluids.

Findings

The aspect ratio law precisely matches laboratory vortex observations.

The law applies to both cyclones and anticyclones.

It is consistent with natural vortex observations like meddies and Jupiter's storms.

Abstract

We validate a new law for the aspect ratio $\alpha = H/L$ of vortices in a rotating, stratified flow, where $H$ and $L$ are the vertical half-height and horizontal length scale of the vortices. The aspect ratio depends not only on the Coriolis parameter f and buoyancy (or Brunt-Vaisala) frequency $\bar{N}$ of the background flow, but also on the buoyancy frequency $N_c$ within the vortex and on the Rossby number $Ro$ of the vortex such that $\alpha = f \sqrt{[Ro (1 + Ro)/(N_c^2- \bar{N}^2)]}$. This law for $\alpha$ is obeyed precisely by the exact equilibrium solution of the inviscid Boussinesq equations that we show to be a useful model of our laboratory vortices. The law is valid for both cyclones and anticyclones. Our anticyclones are generated by injecting fluid into a rotating tank filled with linearly-stratified salt water. The vortices are far from the top and bottom boundaries of the tank, so there is no Ekman circulation. In one set of experiments, the vortices viscously decay, but as they do, they continue to obey our law for $\alpha$, which decreases over time. In a second set of experiments, the vortices are sustained by a slow continuous injection after they form, so they evolve more slowly and have larger |Ro|, but they also obey our law for $\alpha$. The law for $\alpha$ is not only validated by our experiments, but is also shown to be consistent with observations of the aspect ratios of Atlantic meddies and Jupiter's Great Red Spot and Oval BA. The relationship for $\alpha$ is derived and examined numerically in a companion paper by Hassanzadeh et al. (2012).