Global continua of periodic solutions of singular first-order Hamiltonian systems of N-vortex type

Abstract

The paper deals with singular first order Hamiltonian systems of the form \[ kzk(t)=J∇zk H(z(t)), zk(t) ∈ ⊂ R2,\ k=1,…,N, \] where J∈R2×2 defines the standard symplectic structure in R2, and the Hamiltonian H is of N-vortex type: \[ H(z1,…,zN) = -12π Σj≠ k=1N j k |zj-zk| - F(z). \] This is defined on the configuration space \(z1,…,zN)∈ 2N:zj≠ zk for j≠ k\ of N different points in the domain ⊂R2. The function F:N may have additional singularities near the boundary of N. We prove the existence of a global continuum of periodic solutions z(t)=(z1(t),…,zN(t))∈N that emanates, after introducing a suitable singular limit scaling, from a relative equilibrium Z(t)∈R2N of the N-vortex problem in the whole plane (where F=0). Examples for Z include Thomson's vortex configurations, or equilateral triangle solutions. The domain need not be simply connected. A special feature is that the associated action integral is not defined on an open subset of the space of 2π-periodic H1/2 functions, the natural form domain for first order Hamiltonian systems. This is a consequence of the singular character of the Hamiltonian. Our main tool in the proof is a degree for S1-equivariant gradient maps that we adapt to this class of potential operators.