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

Abstract

We derive a relationship for the vortex aspect ratio α (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 Nc and in the background fluid outside the vortex N, the Coriolis parameter f, and the Rossby number Ro of the vortex: α2 = Ro(1+Ro) f2/(Nc2-N2). 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 α has many consequences for equilibrium vortices in rotating stratified flows. For example, cyclones must have Nc2 > N2; weak anticyclones (with |Ro| < 1) must have Nc2 < N2; and strong anticyclones must have Nc2 > N2. We verify our relation for α 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 α, and generally they differ significantly from the values obtained from the much-cited conjecture that α = f/N$ in quasi-geostrophic vortices.