Localization for alloy-type models with non-monotone potentials

Abstract

We consider a family of self-adjoint operators [Hω = - + λ Vω, ω ∈ = k ∈ d ,] on the Hilbert space 2 (d) or L2 (d). Here denotes the Laplace operator (discrete or continuous), Vω is a multiplication operator given by the function Vω (x) = Σk ∈ d ωk u(x-k) on d, or Vω (x) = Σk ∈ d ωk U(x-k) on d, and λ > 0 is a real parameter modeling the strength of the disorder present in the model. The functions u:d and U:d are called single-site potential. Moreover, there is a probability measure on modeling the distribution of the individual configurations ω ∈ . The measure = Πk ∈ d μ is a product measure where μ is some probability measure on satisfying certain regularity assumptions. The operator on L2 (d) is called alloy-type model, and its analogue on 2 (d) discrete alloy-type model. This thesis refines the methods of multiscale analysis and fractional moments in the case where the single-site potential is allowed to change its sign. In particular, we develop the fractional moment method and prove exponential localization for the discrete alloy-type model in the case where the support of u is finite and u has fixed sign at the boundary of its support. We also prove a Wegner estimate for the discrete alloy-type model in the case of exponentially decaying but not necessarily finitely supported single-site potentials. This Wegner estimate is applicable for a proof of localization via multiscale analysis.