Asymptotic stability of critical pulled fronts via resolvent expansions near the essential spectrum

TL;DR

This paper investigates the nonlinear stability of pulled fronts in scalar parabolic equations, establishing universal algebraic decay rates and analyzing how perturbation localization influences decay, using resolvent operator techniques.

Contribution

It provides a general framework for stability analysis of pulled fronts, extending known results from specific models like Fisher-KPP to broader classes of equations.

Findings

Established sharp algebraic decay rates for perturbations.

Described the influence of spatial localization on decay rates.

Developed resolvent operator methods for stability analysis.

Abstract

We study nonlinear stability of pulled fronts in scalar parabolic equations on the real line of arbitrary order, under conceptual assumptions on existence and spectral stability of fronts. In this general setting, we establish sharp algebraic decay rates and temporal asymptotics of perturbations to the front. Some of these results are known for the specific example of the Fisher-KPP equation, and our results can thus be viewed as establishing universality of some aspects of this simple model. We also give a precise description of how the spatial localization of perturbations to the front affects the temporal decay rate, across the full range of localizations for which asymptotic stability holds. Technically, our approach is based on a detailed study of the resolvent operator for the linearized problem, through which we obtain sharp linear time decay estimates that allow for a direct nonlinear analysis.