Branching Brownian Motion Conditioned on Particle Numbers

Abstract

We study analytically the order and gap statistics of particles at time t for the one dimensional branching Brownian motion, conditioned to have a fixed number of particles at t. The dynamics of the process proceeds in continuous time where at each time step, every particle in the system either diffuses (with diffusion constant D), dies (with rate d) or splits into two independent particles (with rate b). We derive exact results for the probability distribution function of gk(t) = xk(t) - xk+1(t), the distance between successive particles, conditioned on the event that there are exactly n particles in the system at a given time t. We show that at large times these conditional distributions become stationary P(gk, t ∞|n) = p(gk|n). We show that they are characterised by an exponential tail p(gk|n) [-|b - d|2 D ~gk] for large gaps in the subcritical (b < d) and supercritical (b > d) phases, and a power law tail p(gk) 8(Db)gk-3 at the critical point (b = d), independently of n and k. Some of these results for the critical case were announced in a recent letter [K. Ramola, S. N. Majumdar and G. Schehr, Phys. Rev. Lett. 112, 210602 (2014)].