Counter-flow induced clustering: Exact results

TL;DR

This paper presents an exact analysis of clustering phenomena in a non-ergodic two-species exclusion process with impurities, revealing phase behavior, correlations, and the influence of initial configurations, with connections to active matter models.

Contribution

It introduces an exactly solvable model demonstrating how counter-flow induces clustering and explores the effects of non-ergodicity and initial conditions on phase transitions.

Findings

Identification of free flowing and clustering phases.

Growth of n-point correlations indicating macroscopic clustering.

Effect of initial configuration rearrangement on clustering onset.

Abstract

We analyze the cluster formation in a non-ergodic stochastic system as a result of counter-flow, with the aid of an exactly solvable model. To illustrate the clustering, a two species asymmetric simple exclusion process with impurities on a periodic lattice is considered, where the impurity can activate flips between the two non-conserved species. Exact analytical results, supported by Monte Carlo simulations, show two distinct phases, free flowing phase and clustering phase. The clustering phase is characterized by constant density and vanishing current of the non-conserved species, whereas the free flowing phase is identified with non-monotonic density and non-monotonic finite current of the same. The $n$-point spatial correlation between $n$ consecutive vacancies grows with increasing $n$ in the clustering phase, indicating the formation of two macroscopic clusters in this phase, one of the vacancies and the other consisting of all the particles. We define a rearrangement parameter that permutes the ordering of particles in the initial configuration, keeping all the input parameters fixed. This rearrangement parameter reveals the significant effect of non-ergodicity on the onset of clustering. For a special choice of the microscopic dynamics, we connect the present model to a system of run and tumble particles used to model active matter, where the two species having opposite net bias manifest the two possible run directions of the run and tumble particles, and the impurities act as tumbling reagents that enable the tumbling process.