Trace singularities in obstacle scattering and the Poisson relation for the relative trace

Abstract

We consider the case of scattering of several obstacles in Rd for d ≥ 2 for the Laplace operator with Dirichlet boundary conditions imposed on the obstacles. In the case of two obstacles, we have the Laplace operators 1 and 2 obtained by imposing Dirichlet boundary conditions only on one of the objects. The relative trace operator g() - g(1) - g(2) + g(0) was introduced in [18] and shown to be trace-class for a large class of functions g, including certrain functions of polynomial growth. When g is sufficiently regular at zero and fast decaying at infinity then, by the Birman-Krein formula, this trace can be computed from the relative spectral shift function rel(λ) = -1π ((λ)), where (λ) is holomorphic in the upper half-plane and fast decaying. In this paper we study the wave-trace contributions to the singularities of the Fourier transform of rel. In particular we prove that rel is real-analytic near zero and we relate the decay of (λ) along the imaginary axis to the first wave-trace invariant of the shortest bounding ball orbit between the obstacles. The function (λ) is important in physics as it determines the Casimir interactions between the objects.