Dimensionality-induced dynamical phase transition in the large deviation of local time density for Brownian motion

Abstract

We study the fluctuation properties of the local time density, T = 1T∫0T δ ( r(t) - 1 ) dt, spent by a d-dimensional Brownian particle at a spherical shell of unit radius, where r(t) denotes the radial distance from the particle to the origin. In the large observation time limit, T ∞, the local time density T obeys the large deviation principle, P( T= ) e-T I(), where the rate function I() is analytic everywhere for d≤ 4. In contrast, for d>4, I() becomes nonanalytic at a specific point =c(d), where c(d)=d(d-4)/(2d-4) depends solely on dimensionality. The singularity signals the occurrence of a first-order dynamical phase transition in dimensions higher than four. Such a transition is accompanied by temporal phase separations in the large deviations of Brownian trajectories. Finally, we validate our theoretical results using a rare-event simulation approach.