Delocalization for random displacement models with Dirac masses

Abstract

We study a random Schroedinger operator, the Laplacian with random Dirac delta potentials on a torus TdL = Rd/LZd, in the thermodynamic limit L∞, for dimension d=2. The potentials are located on a randomly distorted lattice Z2+ω, where the displacements are i.i.d. random variables sampled from a compactly supported probability density. We prove that, if the disorder is sufficiently weak, there exists a certain energy threshold E0>0 above which exponential localization of the eigenfunctions must break down. In fact we can rule out any decay faster than a certain polynomial one. Our results are obtained by translating the problem of the distribution of eigenfunctions of the random Schroedinger operator into a study of the spatial distribution of two point correlation densities of certain random superpositions of Green's functions and its relation with a lattice point problem.