Pinning of a renewal on a quenched renewal

Abstract

We introduce the pinning model on a quenched renewal, which is an instance of a (strongly correlated) disordered pinning model. The potential takes value 1 at the renewal times of a quenched realization of a renewal process σ, and 0 elsewhere, so nonzero potential values become sparse if the gaps in σ have infinite mean. The "polymer" -- of length σN -- is given by another renewal τ, whose law is modified by the Boltzmann weight (βΣn=1N 1\σn∈τ\). Our assumption is that τ and σ have gap distributions with power-law-decay exponents 1+α and 1+ α respectively, with α≥ 0, α>0. There is a localization phase transition: above a critical value βc the free energy is positive, meaning that τ is pinned on the quenched renewal σ. We consider the question of relevance of the disorder, that is to know when βc differs from its annealed counterpart βc ann. We show that βc=βc ann whenever α+ α ≥ 1, and βc=0 if and only if the renewal τσ is recurrent. On the other hand, we show βc>βc ann when α+32\, α <1. We give evidence that this should in fact be true whenever α+ α<1, providing examples for all such α, α of distributions of τ,σ for which βc>βc ann. We additionally consider two natural variants of the model: one in which the polymer and disorder are constrained to have equal numbers of renewals (σN=τN), and one in which the polymer length is τN rather than σN. In both cases we show the critical point is the same as in the original model, at least when α>0.