Static fluctuations of a thick 1D interface in the 1+1 Directed Polymer formulation

Abstract

Experimental realizations of a 1D interface always exhibit a finite microscopic width >0; its influence is erased by thermal fluctuations at sufficiently high temperatures, but turns out to be a crucial ingredient for the description of the interface fluctuations below a characteristic temperature Tc(). Exploiting the exact mapping between the static 1D interface and a 1+1 Directed Polymer (DP) growing in a continuous space, we study analytically both the free-energy and geometrical fluctuations of a DP, at finite temperature T, with a short-range elasticity and submitted to a quenched random-bond Gaussian disorder of finite correlation length . We derive the exact `time'-evolution equations of the disorder free-energy F(t,y), its derivative η (t,y), and their respective two-point correlators C(t,y) and R(t,y). We compute the exact solution of its linearized evolution Rlin(t,y), and we combine its qualitative behavior and the asymptotic properties known for an uncorrelated disorder (=0), to construct a `toymodel' leading to a simple description of the DP. This model is characterized by Brownian-like free-energy fluctuations, correlated at small |y|<, of amplitude D∞(T,). We present an extended scaling analysis of the roughness predicting D∞ 1/T at high-temperatures and D∞ 1/Tc() at low-temperatures. We identify the connection between the temperature-induced crossover and the full replica-symmetry breaking in previous Gaussian Variational Method computations. Finally we discuss the consequences of the low-temperature regime for two experimental realizations of KPZ interfaces, namely the static and quasistatic behavior of magnetic domain walls and the high-velocity steady-state dynamics of interfaces in liquid crystals.