The Random Walk Pinning Model II: Upper bounds on the free energy and disorder relevance

Abstract

This article investigates the question of disorder relevance for the continuous-time Random Walk Pinning Model (RWPM) and completes the results of our companion paper. The RWPM considers a continuous time random walk X=(Xt)t≥ 0, whose law is modified by a Gibbs weight given by (β ∫0T 1\Xt=Yt\ dt), where Y=(Yt)t≥ 0 is a quenched trajectory of a second (independent) random walk and β ≥ 0 is the inverse temperature. The random walk Y has the same distribution as X but a jump rate ≥ 0, interpreted as the disorder intensity. For fixed 0, the RWPM undergoes a localization phase transition as β crosses a critical threshold βc(). The question of disorder relevance then consists in determining whether a disorder of arbitrarily small intensity changes the properties of the phase transition. We focus our analysis on the case of transient γ-stable walks on Z, i.e. random walks in the domain of attraction of a γ-stable law, with γ∈ (0,1). In the present paper, we show that disorder is relevant when γ ∈ (0,23], namely that βc()>βc(0) for every >0. We also provide lower bounds on the critical point shift, which are matching the upper bounds obtained in our companion paper. Interestingly, in the marginal case γ = 23, disorder is always relevant, independently of the fine properties of the random walk distribution. When γ ∈ (23,1), our companion paper proves that disorder is irrelevant (in particular βc()=βc(0) for small enough). We provide here an upper bound on the free energy in the regime γ∈ ( 2 3,1) that highlights the fact that although disorder is irrelevant, it still has a non-trivial effect on the phase transition, at any >0.