Dynamical phase transition in the first-passage probability of a Brownian motion

Abstract

We study theoretically, experimentally and numerically the probability distribution F(tf|x0,L) of the first passage times tf needed by a freely diffusing Brownian particle to reach a target at a distance L from the initial position x0, taken from a normalized distribution (1/σ)\, g(x0/σ) of finite width σ. We show the existence of a critical value bc of the parameter b=L/σ, which determines the shape of F(tf|x0,L). For b>bc the distribution F(tf|x0,L) has a maximum and a minimum whereas for b<bc it is a monotonically decreasing function of tf. This dynamical phase transition is generated by the presence of two characteristic times σ2/D and L2/D, where D is the diffusion coefficient. The theoretical predictions are experimentally checked on a Brownian bead whose free diffusion is initialized by an optical trap which determines the initial distribution g(x0/σ). The presence of the phase transition in 2d has also been numerically estimated using a Langevin dynamics.