On the local eigenvalue statistics for random band matrices in the localization regime

Abstract

We study the local eigenvalue statistics ω,EN associated with the eigenvalues of one-dimensional, (2N+1) × (2N+1) random band matrices with independent, identically distributed, real random variables and band width growing as Nα, for 0 < α < 12. We consider the limit points associated with the random variables ω,EN [I], for I ⊂ R, and E ∈ (-2,2). For Gaussian distributed random variables with 0 ≤ α < 17, we prove that this family of random variables has nontrivial limit points for almost every E ∈ (-2,2), and that these limit points are Poisson distributed with positive intensities. The proof is based on an analysis of the characteristic functions of the random variables ω,EN [I] and associated quantities related to the intensities, as N tends towards infinity, and employs known localization bounds of schenker, peled, et. al., and the strong Wegner and Minami estimates peled, et. al.. Our more general result applies to random band matrices with random variables having absolutely continuous distributions with bounded densities. Under the hypothesis that the localization bounds hold for 0 < α < 12, we prove that any nontrivial limit points of the random variables ω,EN [I] are distributed according to Poisson distributions.