Probing phase transitions of finite directed polymers near a corrugated wall via two-replica analysis

TL;DR

This paper investigates the phase transition behavior of a finite directed polymer near a corrugated wall, analyzing the effects of quenched disorder and deriving criteria for pinning transition differences between annealed and quenched systems.

Contribution

It provides an explicit criterion for distinguishing pinning transitions in quenched versus annealed disordered systems using two-replica analysis.

Findings

Transition points differ between quenched and annealed systems in the thermodynamic limit.

A finite 'gray zone' exists where the difference in transition points is negligible.

Results help clarify the relevance of quenched disorder in phase transitions.

Abstract

We study the pinning transition in a (1+1)-dimensional lattice model of a fluctuating interface interacting with a corrugated impenetrable wall. The interface is modeled as an $N$-step directed one-dimensional random walk on the half-line $x \ge 0$. Its interaction with the wall is described by a quenched, site-dependent, short-ranged random potential $u_j$ ($j = 1,\ldots,N$), distributed according to $Q(u_j)$ and localized at $x = 0$. By computing the first two disorder--averaged moments of the partition function, $\langle G_N \rangle$ and $\langle G_N^2 \rangle$, and by analyzing the analytic structure of the resulting expressions, we derive an explicit criterion for the coincidence or distinction of the pinning transitions in annealed and quenched systems. We show that, although the transition points of the annealed and quenched systems are always different in the thermodynamic limit, for finite systems there exists a "gray zone" in which this difference is hardly detectable. Our results may help reconcile conflicting views on whether quenched disorder is marginally relevant.