Universal Order and Gap Statistics of Critical Branching Brownian Motion

Abstract

We study the order statistics of one dimensional branching Brownian motion in which particles either diffuse (with diffusion constant D), die (with rate d) or split into two particles (with rate b). At the critical point b=d which we focus on, we show that, at large time t, the particles are collectively bunched together. We find indeed that there are two length scales in the system: (i) the diffusive length scale Dt which controls the collective fluctuations of the whole bunch and (ii) the length scale of the gap between the bunched particles D/b. We compute the probability distribution function P(gk,t|n) of the kth gap gk = xk - xk+1 between the kth and (k+1)th particles given that the system contains exactly n>k particles at time t. We show that at large t, it converges to a stationary distribution P(gk,t ∞|n) = p(gk|n) with an algebraic tail p(gk|n) 8(D/b) gk-3, for gk 1, independent of k and n. We verify our predictions with Monte Carlo simulations.