Precise propagation profile for some monostable free boundary problems in time-periodic media

TL;DR

This paper establishes the existence, uniqueness, and sharp convergence of semi-wave solutions in a time-periodic, monostable free boundary reaction-diffusion model, generalizing previous results to heterogeneous environments without KPP restrictions.

Contribution

It proves the first sharp convergence result for a general monostable free boundary problem in a heterogeneous, time-periodic setting, extending prior autonomous and KPP-specific findings.

Findings

Existence and uniqueness of semi-wave solutions.

Precise convergence of solutions to semi-waves over time.

Applicability of methods to broader free boundary problems in heterogeneous media.

Abstract

We consider reaction-diffusion equations of the form \begin{equation*} u_t - d u_{xx} = f(t,u), \quad t>0,\ \ x \in [g(t), h(t)], \end{equation*} where $f(t,u)$ is periodic in $t$ and monostable in $u$, and the interval $[g(t), h(t)]$ represents the one dimensional population range of a species with density $u(t,x)$ at time $t$ and spatial location $x$. The free boundaries $x=g(t)$ and $x=h(t)$ evolve subject to a ``preferred population density" condition at the habitat edges. Analogous to the traveling wave solutions in the corresponding Cauchy problem, semi-wave solutions play a fundamental role in understanding the propagation phenomena governed by the free boundary problem here. But in contrast to the Cauchy problem, where the KPP condition plays a subtle role in the precise approximation of its solution (with compactly supported initial function) by the traveling wave solution with minimal speed, here we prove the existence and uniqueness of a semi-wave in a general monostable setting, and obtain a precise description of the convergence of the solution toward the semi-wave as time goes to infinity, where the KPP condition plays no special role. Previously, such a sharp result was proved for a free boundary model only when $f$ is autonomous ($f=f(u)$, see \cite{D} or \cite{DL15} for a related free boundary model), or a less precise result was obtained in the time-periodic case under an extra strong KPP condition on $f$ (see \cite{MDW}, or \cite{DGP} for a related free boundary model). This work appears to be the first to prove the sharp convergence result for a general monostable free boundary problem in a heterogeneous environment, and we believe the methods developed here should have applications to related free boundary problems in heterogeneous media with nonlinearities more general than those of KPP type.