Quasi-stationary behavior of the stochastic FKPP equation on the circle

Abstract

We consider the stochastic Fisher-Kolmogorov-Petrovsky-Piscunov (FKPP) equation on the circle S, equation* ∂t u(t,x) \,= α2 u +β\,u(1-u) + γ\,u(1-u)\,W, (t,x)∈(0,∞)× S, equation* where W is space-time white noise. While any solution will eventually be absorbed at one of two states, the constant 1 and the constant 0 on the circle, essentially nothing had been established about the absorption time (also called the fixation time in population genetics), or about the long-time behavior prior to absorption. We establish the existence and uniqueness of the quasi-stationary distribution (QSD) for the solution of the stochastic FKPP. Moreover, we show that the solution conditioned on not being absorbed at time t converges to this unique QSD as t∞, for any initial distribution, and characterize the leading-order asymptotics for the tail distribution of the fixation time. We obtain explicit calculations in the neutral case (β=0), quantifying the effect of spatial diffusion on fixation time. We explicitly express the fixation rate in terms of the migration rate α for all α∈ (0,∞), finding in particular that the fixation rate is given by γ[1-γ12α+O(γ2α2)] for fast migration and π2α[1-8αγ+O(α2γ2)] for slow migration. Our proof relies on the observation that the absorbed (or killed) stochastic FKPP is dual to a system of 2-type branching-coalescing Brownian motions killed when one type dies off, and on leveraging the relationship between these two killed processes.