Shape dynamics of N point vortices on the sphere

We give a geometric account of the relative motion or the shape dynamics of N point vortices on the sphere exploiting the SO(3)-symmetry of the system. The main idea is to bypass the technical difficulty of the SO(3)-reduction by first lifting the dynamics from S-2 to C-2. We then perform the U(2)-reduction using a dual pair to obtain a Lie-Poisson dynamics for the shape dynamics. This Lie-Poisson structure helps us find a family of Casimirs for the shape dynamics. We further reduce the system by TN-1-symmetry to obtain a Poisson structure for the shape dynamics involving fewer shape variables than those of the previous work by Borisov and Pavlov. As an application of the shape dynamics, we prove that the tetrahedron relative equilibria are stable when all of their circulations have the same sign, generalizing some existing results on tetrahedron relative equilibria of identical vortices.