Tuning the strength of emergent correlations in a Brownian gas via batch resetting

Abstract

We study a gas of N diffusing particles on the line subject to batch resetting: at rate r, a uniformly random subset of m particles is reset to the origin. Despite the absence of interactions, the dynamics generates a nonequilibrium stationary state (NESS) with long-range correlations. We obtain exact results, both for the NESS and for the time dependence of the correlations, which are valid for arbitrary m and N. By varying m, the system interpolates between an uncorrelated regime (m=1) and the fully synchronous resetting case (m=N). For all 1<m<N, correlations exhibit a non-monotonic time dependence due to the emergence of an intrinsic decorrelation mechanism. In the stationary state, the correlation strength can be tuned by varying m, and it displays a transition at a critical value Nc=6. Our predictions extend straightforwardly to any spatial dimension d and the critical value Nc=6 remains the same in all dimensions. Our predictions are testable in existing experimental setups on optically trapped colloidal particles.