Extremal Steklov-Neumann Eigenvalues

Abstract

Let be a bounded open planar domain with smooth connected boundary, , that has been partitioned into two disjoint components, = S N. We consider the Steklov-Neumann eigenproblem on , where a harmonic function is sought that satisfies the Steklov boundary condition on S and the Neumann boundary condition on N. We pose the extremal eigenvalue problems (EEPs) of minimizing/maximizing the k-th non-trivial Steklov-Neumann eigenvalue among boundary partitions of prescribed measure. We formulate a relaxation of these EEPs in terms of weighted Steklov eigenvalues where an L∞() density replaces the boundary partition. For these relaxed EEPs, we establish existence and prove optimality conditions. We also prove a homogenization result that allows us to use solutions to the relaxed EEPs to infer properties of solutions to the original EEPs. For a disk, we provide numerical and asymptotic evidence that the minimizing arrangement of S N for the k-th eigenvalue consists of k+1 connected components that are symmetrically arranged on the boundary. For a disk, for k = 1, the constant density is a maximizer for the relaxed problem; we also provide numerical and asymptotic evidence that for k 2, the maximizing density for the relaxed problem is a non-trivial function; a sequence of rapidly oscillating Steklov/Neumann boundary conditions approach the supremum value.