Particle-number distribution in large fluctuations at the tip of branching random walks

Abstract

We investigate properties of the particle distribution near the tip of one-dimensional branching random walks at large times t, focusing on unusual realizations in which the rightmost lead particle is very far ahead of its expected position - but still within a distance smaller than the diffusion radius t. Our approach consists in a study of the generating function G x(λ)=Σn λn pn( x) for the probabilities pn( x) of observing n particles in an interval of given size x from the lead particle to its left, fixing the position of the latter. This generating function can be expressed with the help of functions solving the Fisher-Kolmogorov-Petrovsky-Piscounov (FKPP) equation with suitable initial conditions. In the infinite-time and large- x limits, we find that the mean number of particles in the interval grows exponentially with x, and that the generating function obeys a nontrivial scaling law, depending on x and λ through the combined variable [ x-f(λ)]3/ x2, where f(λ) -(1-λ)-[-(1-λ)]. From this property, one may conjecture that the growth of the typical particle number with the size of the interval is slower than exponential, but, surprisingly enough, only by a subleading factor at large x. The scaling we argue is consistent with results from a numerical integration of the FKPP equation.