Spreading speed of locally regulated population models in macroscopically heterogeneous environments

Abstract

We consider a certain lattice branching random walk with on-site competition and in an environment which is heterogeneous at a macroscopic scale 1/ in space and time. This can be seen as a model for the spatial dynamics of a biological population in a habitat which is heterogeneous at a large scale (mountains, temperature or precipitation gradient…). The model incorporates another parameter, K, which is a measure of the local population density. We study the model in the limit when first 0 and then K∞. In this asymptotic regime, we show that the rescaled position of the front as a function of time converges to the solution of an explicit ODE. We further discuss the relation with another popular model of population dynamics, the Fisher-KPP equation, which arises in the limit K∞. Combined with known results on the Fisher-KPP equation, our results show in particular that the limits 0 and K∞ do not commute in general. We conjecture that an interpolating regime appears when K and 1/ are of the same order.