Resonances and Spectral Shift Function for a Magnetic SCHR\"Odinger Operator

Abstract

We consider the 3D Schr\"odinger operator H0 with constant magnetic field and subject to an electric potential v0 depending only on the variable along the magnetic field x3. The operator H0 has infinitely many eigenvalues of infinite multiplicity embedded in its continuous spectrum. We perturb H0 by smooth scalar potentials V=O((x1,x2)>-x3>-), >2, >1. We assume also that V and v0 have an analytic continuation, in the magnetic field direction, in a complex sector outside a compact set. We define the resonances of H=H0+V as the eigenvalues of the non-selfadjoint operator obtained from H by analytic distortions of x3. We study their distribution near any fixed real eigenvalue of H0, 2bq+ for q∈. In a ring centered at 2bq+ with radiuses (r,2r), we establish an upper bound, as r tends to 0, of the number of resonances. This upper bound depends on the decay of V at infinity only in the directions (x1,x2). Finally, we deduce a representation of the derivative of the spectral shift function (SSF) for the operator pair (H0,H) in terms of resonances. This representation justifies the Breit-Wigner approximation and implies a local trace formula.