Collective behaviour of large number of vortices in the plane

Abstract

We investigate the dynamics of N point vortices in the plane, in the limit of large N. We consider relative equilibria, which are rigidly rotating lattice-like configurations of vortices. These configurations were observed in several recent experiments [Durkin and Fajans, Phys. Fluids (2000) 12, 289-293; Grzybowski et.al PRE (2001)64, 011603]. We show that these solutions and their stability are fully characterized via a related aggregation model which was recently investigated in the context of biological swarms [Fetecau et.al., Nonlinearity (2011) 2681; Bertozzi et.al., M3AS (2011)]. By utilizing this connection, we give explicit analytic formulae for many of the configurations that have been observed experimentally. These include configurations of vortices of equal strength; the N+1 configurations of N vortices of equal strength and one vortex of much higher strength; and more generally, N+K configurations. We also give examples of configurations that have not been studied experimentally, including N+2 configurations where N vortices aggregate inside an ellipse. Finally, we introduce an artificial ``damping'' to the vortex dynamics, in an attempt to explain the phenomenon of crystalization that is often observed in real experiments. The diffusion breaks the conservative structure of vortex dynamics so that any initial conditions converge to the lattice-like relative equilibrium.