Dynamics at barriers in bidirectional two-lane exclusion processes

TL;DR

This paper investigates the steady state behaviors of a two-lane exclusion process with particles moving in opposite directions, revealing two distinct types of localized and delocalized clusters and their impact on current decay.

Contribution

It introduces a detailed analysis of two different steady states in a bidirectional two-lane exclusion process, including conditions for their occurrence and effects of disorder.

Findings

Localized clusters with exponential current decay

Delocalized clusters with inverse proportional current decay

Disorder induces logarithmic decay of current

Abstract

A two-lane exclusion process is studied where particles move in the two lanes in opposite directions and are able to change lanes. The focus is on the steady state behavior in situations where a positive current is constrained to an extended subsystem (either by appropriate boundary conditions or by the embedding environment) where, in the absence of the constraint, the current would be negative. We have found two qualitatively different types of steady states and formulated the conditions of them in terms of the transition rates. In the first type of steady state, a localized cluster of particles forms with an anti-shock located in the subsystem and the current vanishes exponentially with the extension of the subsystem. This behavior is analogous to that of the one-lane partially asymmetric simple exclusion process, and can be realized e.g. when the local drive is induced by making the jump rates in two lanes unequal. In the second type of steady state, which is realized e.g. if the local drive is induced purely by the bias in the lane change rates, and which has thus no counterpart in the one-lane model, a delocalized cluster of particles forms which performs a diffusive motion as a whole and, as a consequence, the current vanishes inversely proportionally to the extension of the subsystem. The model is also studied in the presence of quenched disordered, where, in case of delocalization, phenomenological considerations predict anomalously slow, logarithmic decay of the current with the system size in contrast with the usual power-law.