Giant Fluctuations in Self-Propelled Particles with Age-Dependent Switching

Abstract

We investigate the transport and fluctuation properties of self-propelled particles whose motion is governed by an age-dependent phase-switching mechanism. The dynamics alternate between a Markovian downstream phase with a constant switching probability r and a semi-Markovian upstream phase in which the age-dependent hazard probability a/(b+c) decays with the internal clock c, representing persistent orientation. The time-averaged velocity, as an order parameter, shows a continuous transition at a=1 which separates an upstream-dominated ballistic regime (a<1) from an ergodic diffusive regime (a>1). Through generating-function methods and discrete-time moment recurrences, we derive exact expressions for the propagator and determine the long-time asymptotics of the mean displacement and variance. At the critical point a=1, the system exhibits giant fluctuations, with the variance scaling ballistically up to a logarithmic correction, Var(xT) T2 / T. These results demonstrate how slowly decaying reorientation probabilities lead to a marginal breakdown of the Central Limit Theorem, enabling unusually high-variance exploratory dynamics in biased environments.