On the eigenvalues of the Robin Laplacian with a complex parameter

Abstract

We study the spectrum of the Robin Laplacian with a complex Robin parameter α on a bounded Lipschitz domain . We start by establishing a number of properties of the corresponding operator, such as generation properties, local analytic dependence of the eigenvalues and eigenspaces on α ∈ C, and basis properties of the eigenfunctions. Our focus, however, is on bounds and asymptotics for the eigenvalues as functions of α: we start by providing estimates on the numerical range of the associated operator, which lead to new eigenvalue bounds even in the case α ∈ R. For the asymptotics of the eigenvalues as α ∞ in C, in place of the min-max characterisation of the eigenvalues and Dirichlet-Neumann bracketing techniques commonly used in the real case, we exploit the duality between the eigenvalues of the Robin Laplacian and the eigenvalues of the Dirichlet-to-Neumann map. We use this to show that every Robin eigenvalue either diverges to ∞ in C or converges to a point in the spectrum of the Dirichlet Laplacian, and also to give a comprehensive treatment of the special cases where is an interval, a hyperrectangle or a ball. This leads to the conjecture that on a general smooth domain in dimension d≥ 2 all eigenvalues converge to the Dirichlet spectrum if Re\, α remains bounded from below as α ∞, while if Re\, α -∞, then there is a family of divergent eigenvalue curves, each of which behaves asymptotically like -α2.