Branching Brownian motion with absorption and the all-time minimum of branching Brownian motion with drift

Abstract

We study a dyadic branching Brownian motion on the real line with absorption at 0, drift μ ∈ R and started from a single particle at position x>0. When μ is large enough so that the process has a positive probability of survival, we consider K(t), the number of individuals absorbed at 0 by time t and for s 0 the functions ωs(x):= Ex[sK(∞)]. We show that ωs<∞ if and only of s∈[0,s0] for some s0>1 and we study the properties of these functions. Furthermore, for s=0, ω(x) := ω0(x) =Px(K(∞)=0) is the cumulative distribution function of the all time minimum of the branching Brownian motion with drift started at 0 without absorption. We give three descriptions of the family ωs, s∈ [0,s0] through a single pair of functions, as the two extremal solutions of the Kolmogorov-Petrovskii-Piskunov (KPP) traveling wave equation on the half-line, through a martingale representation and as an explicit series expansion. We also obtain a precise result concerning the tail behavior of K(∞). In addition, in the regime where K(∞)>0 almost surely, we show that u(x,t) := Px(K(t)=0) suitably centered converges to the KPP critical travelling wave on the whole real line.