On the Kunz-Souillard approach to localization for the discrete one dimensional generalized Anderson model

Abstract

We prove dynamical and spectral localization at all energies for the discrete generalized Anderson model via the Kunz-Souillard approach to localization. This is an extension of the original Kunz-Souillard approach to localization for Schr\"odinger operators, to the case where a single random variable determines the potential on a block of an arbitrary, but fixed, size α. For this model, we also give a description of the almost sure spectrum as a set and prove uniform positivity of the Lyapunov exponents. In fact, regarding positivity of the Lyapunov exponents, we prove a stronger statement where we also allow finitely supported distributions. We also show that for any size α generalized Anderson model, there exists some finitely supported distribution for which the Lyapunov exponent will vanish for at least one energy. Moreover, restricting to the special case α=1, we describe a pleasant consequence of this modified technique to the original Kunz-Souillard approach to localization. In particular, we demonstrate that actually the single operator T1 is a strict contraction in L2(R), whereas before it was only shown that the second iterate of T1 is a strict contraction.