Run-and-tumble particle in one-dimensional confining potential: Steady state, relaxation and first passage properties

Abstract

We study the dynamics of a one-dimensional run and tumble particle subjected to confining potentials of the type V(x) = α \, |x|p, with p>0. The noise that drives the particle dynamics is telegraphic and alternates between 1 values. We show that the stationary probability density P(x) has a rich behavior in the (p, α)-plane. For p>1, the distribution has a finite support in [x-,x+] and there is a critical line αc(p) that separates an active-like phase for α > αc(p) where P(x) diverges at x, from a passive-like phase for α < αc(p) where P(x) vanishes at x. For p<1, the stationary density P(x) collapses to a delta function at the origin, P(x) = δ(x). In the marginal case p=1, we show that, for α < αc, the stationary density P(x) is a symmetric exponential, while for α > αc, it again is a delta function P(x) = δ(x). For the special cases p=2 and p=1, we obtain exactly the full time-dependent distribution P(x,t), that allows us to study how the system relaxes to its stationary state. In addition, in these two cases, we also study analytically the full distribution of the first-passage time to the origin. Numerical simulations are in complete agreement with our analytical predictions.