Vortex sheet solutions for the Ginzburg-Landau system in cylinders: symmetry and global minimality

Abstract

We consider the Ginzburg-Landau energy Eε for RM-valued maps defined in a cylinder shape domain BN× (0,1)n satisfying a degree-one vortex boundary condition on ∂ BN× (0,1)n in dimensions M≥ N≥ 2 and n≥ 1. The aim is to study the radial symmetry of global minimizers of this variational problem. We prove the following: if N≥ 7, then for every ε>0, there exists a unique global minimizer which is given by the non-escaping radially symmetric vortex sheet solution uε(x,z)=(fε(|x|) x|x|, 0RM-N), ∀ x∈ BN that is invariant in z∈ (0,1)n. If 2≤ N ≤ 6 and M≥ N+1, the following dichotomy occurs between escaping and non-escaping solutions: there exists εN>0 such that if ε∈ (0, εN), then every global minimizer is an escaping radially symmetric vortex sheet solution of the form R uε where uε(x,z)=(fε(|x|) x|x|, 0RM-N-1, gε(|x|)) is invariant in z-direction with gε>0 in (0,1) and R∈ O(M) is an orthogonal transformation keeping invariant the space RN× \0RM-N\; if ε≥ εN, then the non-escaping radially symmetric vortex sheet solution uε(x,z)=(fε(|x|) x|x|, 0RM-N), ∀ x∈ BN, z∈ (0,1)n is the unique global minimizer; moreover, there are no bounded escaping solutions in this case. We also discuss the problem of vortex sheet SM-1-valued harmonic maps.