Nonequilibrium Steady State of a Weakly-Driven Kardar-Parisi-Zhang Equation

Abstract

We consider an infinite interface in d>2 dimensions, governed by the Kardar-Parisi-Zhang (KPZ) equation with a weak Gaussian noise which is delta-correlated in time and has short-range spatial correlations. We study the probability distribution of the interface height H at a point of the substrate, when the interface is initially flat. We show that, in a stark contrast with the KPZ equation in d<2, this distribution approaches a non-equilibrium steady state. The time of relaxation toward this state scales as the diffusion time over the correlation length of the noise. We study the steady-state distribution P(H) using the optimal-fluctuation method. The typical, small fluctuations of height are Gaussian. For these fluctuations the activation path of the system coincides with the time-reversed relaxation path, and the variance of P(H) can be found from a minimization of the (nonlocal) equilibrium free energy of the interface. In contrast, the tails of P(H) are nonequilibrium, non-Gaussian and strongly asymmetric. To determine them we calculate, analytically and numerically, the activation paths of the system, which are different from the time-reversed relaxation paths. We show that the slower-decaying tail of P(H) scales as - P(H) |H|, while the faster-decaying tail scales as - P(H) |H|3. The slower-decaying tail has important implications for the statistics of directed polymers in random potential.