Steady State and Dynamics of Driven Diffusive Systems with Quenched Disorder

TL;DR

This paper investigates how quenched disorder affects the steady-state and dynamics of driven diffusive lattice gases, revealing phase separation and altered correlation behavior depending on wave speed.

Contribution

It provides an exact steady-state measure for certain models with quenched disorder and explores the impact of disorder on dynamical correlations and phase behavior.

Findings

Exact steady-state measure for models with quenched disorder

Disorder relevance depends on kinematic wave speed

Phase separation occurs when wave speed vanishes

Abstract

We study the effect of quenched disorder on nonequilibrium systems of interacting particles, specifically, driven diffusive lattice gases with spatially disordered jump rates. The exact steady-state measure is found for a class of models evolving by drop-push dynamics, allowing several physical quantities to be calculated. Dynamical correlations are studied numerically in one dimension. We conjecture that the relevance of quenched disorder depends crucially upon the speed of the kinematic waves in the system. Time-dependent correlation functions, which monitor the dissipation of kinematic waves, behave as in pure system if the wave speed is non-zero. When the wave speed vanishes, e.g. for the disordered exclusion process close to half filling, disorder is strongly relevant and induces separation of phases with different macroscopic densities. In this case the exponent characterizing the dynamical correlation function changes.