Strong-disorder expansion of the root-averaged density of states for the Anderson model on the Bethe lattice

Abstract

We study the root-averaged density of states for the Anderson model on the Bethe lattice in the strong-disorder regime. Here the density of states means the root-averaged spectral measure, not a finite-volume eigenvalue counting limit. We assume that the single-site distribution has compact support and has a locally analytic density on an interval I containing a given interval I. Combining the random-walk expansion on the tree with a complex-analytic argument for the single-site Stieltjes transforms, we prove that the scaled averaged diagonal resolvent has a holomorphic continuation to a complex neighborhood of I for all sufficiently large λ. By the Stieltjes inversion formula, the root-averaged density of states measure is absolutely continuous on the scaled energy window λ I, and its density is real analytic and has a finite-order strong-disorder expansion there. In the scaled form E=λ, the leading coefficient is the local density of the single-site distribution. All odd coefficients vanish, and the higher coefficients are finite sums determined by occupation profiles of short closed walks on the tree. For the uniform single-site distribution, we compute the first nonzero correction term explicitly.