First-order condensation transition in the position distribution of a run-and-tumble particle in one dimension

Abstract

We consider a single run-and-tumble particle (RTP) moving in one dimension. We assume that the velocity of the particle is drawn independently at each tumbling from a zero-mean Gaussian distribution and that the run times are exponentially distributed. We investigate the probability distribution P(X,N) of the position X of the particle after N runs, with N 1. We show that in the regime X N3/4 the distribution P(X,N) has a large deviation form with a rate function characterized by a discontinuous derivative at the critical value X=Xc>0. The same is true for X=-Xc due to the symmetry of P(X,N). We show that this singularity corresponds to a first-order condensation transition: for X>Xc a single large jump dominates the RTP trajectory. We consider the participation ratio of the single-run displacements as the order parameter of the system, showing that this quantity is discontinuous at X=Xc. Our results are supported by numerical simulations performed with a constrained Markov chain Monte Carlo algorithm.