Overlaps and Pathwise Localization in the Anderson Polymer Model

Abstract

We consider large time behavior of typical paths under the Anderson polymer measure. If P is the measure induced by rate , simple, symmetric random walk on Zd started at x, this measure is defined as dμ(X)=Z-1 \β∫0T dWX(s)(s)\dP(X) where \Wx:x∈ Zd\ is a field of iid standard, one-dimensional Brownian motions, β>0, >0 and Z the normalizing constant. We establish that the polymer measure gives a macroscopic mass to a small neighborhood of a typical path as T ∞, for parameter values outside the perturbative regime of the random walk, giving a pathwise approach to polymer localization, in contrast with existing results. The localization becomes complete as β2∞ in the sense that the mass grows to 1. The proof makes use of the overlap between two independent samples drawn under the Gibbs measure μ, which can be estimated by the integration by parts formula for the Gaussian environment. Conditioning this measure on the number of jumps, we obtain a canonical measure which already shows scaling properties, thermodynamic limits, and decoupling of the parameters.