The 1D nonlocal Fisher-KPP equation with a top hat kernel. Part 3. The effect of perturbations in the kernel

TL;DR

This paper investigates how small perturbations to the kernel in a nonlocal Fisher-KPP equation affect the solution structure, especially when the diffusion coefficient is small, revealing a transition from regular to singular perturbation regimes.

Contribution

It extends the classical Fisher-KPP model by analyzing the effects of kernel perturbations, highlighting the transition from regular to singular perturbation problems as diffusion decreases.

Findings

Small kernel perturbations lead to regular perturbation problems for large D.

When D is small, the problem becomes a strongly singular perturbation, altering the solution structure.

The study provides insights into the impact of nonlocal effects in reaction-diffusion models.

Abstract

In the third part of this series of papers, we address the same Cauchy problem that was considered in part 1, namely the nonlocal Fisher-KPP equation in one spatial dimension, $u_t = D u_{xx} + u(1-\phi_T*u)$, where $\phi_T*u$ is a spatial convolution with the top hat kernel, $\phi_T(y) \equiv H\left(\frac{1}{4}-y^2\right)$, except that now we include a specified perturbation to this kernel, which we denote as $\overline{\phi}:\mathbb{R}\to \mathbb{R}$. Thus the top hat kernel $\phi_T$ is now replaced by the perturbed kernel $\phi:\mathbb{R} \to \mathbb{R}$, where $\phi(x) = \phi_T(x) + \overline{\phi}(x)~~\forall~~x\in \mathbb{R}$. When the magnitude of the kernel perturbation is small in a suitable norm, the situation is shown to be generally a regular perturbation problem when the diffusivity $D$ is formally of O(1) or larger. However when $D$ becomes small, and in particular, of the same order as the magnitude of the perturbation to the kernel, this becomes a strongly singular perturbation problem, with considerable changes in overall structure. This situation is uncovered in detail In terms of its generic interest, the model forms a natural extension to the classical Fisher-KPP model, with the introduction of the simplest possible nonlocal effect into the saturation term. Nonlocal reaction-diffusion models arise naturally in a variety of (frequently biological or ecological) contexts, and as such it is of fundamental interest to examine its properties in detail, and to compare and contrast these with the well known properties of the classical Fisher-KPP model.