The distribution of the maximum of independent resetting Brownian motions

Abstract

The probability distribution of the maximum Mt of a single resetting Brownian motion (RBM) of duration t and resetting rate r, properly centred and scaled, is known to converge to the standard Gumbel distribution of the classical extreme value theory. This Gumbel law describes the typical fluctuations of Mt around its average (r t) for large t on a scale of O(1). Here we compute the large-deviation tails of this distribution when Mt = O(t) and show that the large-deviation function has a singularity where the second derivative is discontinuous, signalling a dynamical phase transition. Then we consider a collection of independent RBMs with initial (and resetting) positions uniformly distributed with a density over the negative half-line. We show that the fluctuations in the initial positions of the particles modify the distribution of Mt. The average over the initial conditions can be performed in two different ways, in analogy with disordered systems: (i) the annealed case where one averages over all possible initial conditions and (ii) the quenched case where one considers only the contributions coming from typical initial configurations. We show that in the annealed case, the limiting distribution of the maximum is characterized by a new scaling function, different from the Gumbel law but the large-deviation function remains the same as in the single particle case. In contrast, for the quenched case, the limiting (typical) distribution remains Gumbel but the large-deviation behaviors are new and nontrivial. Our analytical results, both for the typical as well as for the large-deviation regime of Mt, are verified numerically with extremely high precision, down to 10-250 for the probability density of Mt.