Propagation of Reactions in Inhomogeneous Media

Abstract

Consider reaction-diffusion equation ut= u + f(x,u) with x∈Rd and general inhomogeneous ignition reaction f 0 vanishing at u=0,1. Typical solutions 0 u 1 transition from 0 to 1 as time progresses, and we study them in the region where this transition occurs. Under fairly general qualitative hypotheses on f we show that in dimensions d 3, the Hausdorff distance of the super-level sets \uε\ and \u 1-ε\ remains uniformly bounded in time for each ε∈(0,1). Thus, u remains uniformly in time close to the characteristic function of \u 12\ in the sense of Hausdorff distance of super-level sets. We also show that \u 12\ expands with average speed (over any long enough time interval) between the two spreading speeds corresponding to any x-independent lower and upper bounds on f. On the other hand, these results turn out to be false in dimensions d 4, at least without further quantitative hypotheses on f. The proof for d 3 is based on showing that as the solution propagates, small values of u cannot escape far ahead of values close to 1. The proof for d 4 involves construction of a counter-example for which this fails. Such results were before known for d=1 but are new for general non-periodic media in dimensions d 2 (some are also new for homogeneous and periodic media). They extend in a somewhat weaker sense to monostable, bistable, and mixed reaction types, as well as to transitions between general equilibria u-<u+ of the PDE, and to solutions not necessarily satisfying u- u u+.