Front Selection in Reaction–Diffusion Systems via Diffusive Normal Forms

IF 2.6 1区数学 Q1 MATHEMATICS, APPLIED

Archive for Rational Mechanics and Analysis Pub Date : 2024-02-13 DOI:10.1007/s00205-024-01961-5

Montie Avery

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Abstract

We show that propagation speeds in invasion processes modeled by reaction–diffusion systems are determined by marginal spectral stability conditions, as predicted by the marginal stability conjecture. This conjecture was recently settled in scalar equations; here we give a full proof for the multi-component case. The main new difficulty lies in precisely characterizing diffusive dynamics in the leading edge of invasion fronts. To overcome this, we introduce coordinate transformations which allow us to recognize a leading order diffusive equation relying only on an assumption of generic marginal pointwise stability. We are then able to use self-similar variables to give a detailed description of diffusive dynamics in the leading edge, which we match with a traveling invasion front in the wake. We then establish front selection by controlling these matching errors in a nonlinear iteration scheme, relying on sharp estimates on the linearization about the invasion front. We briefly discuss applications to parametrically forced amplitude equations, competitive Lotka–Volterra systems, and a tumor growth model.

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通过扩散正常形式进行反应-扩散系统中的前沿选择

我们证明，正如边际稳定性猜想所预测的那样，以反应扩散系统为模型的入侵过程的传播速度是由边际谱稳定性条件决定的。这一猜想最近在标量方程中得到了解决；在此，我们给出了多组分情况下的完整证明。新的主要困难在于如何精确描述入侵前沿的扩散动力学。为了克服这一困难，我们引入了坐标变换，只需假设一般边际点稳定性，就能识别前阶扩散方程。然后，我们就能利用自相似变量来详细描述前沿的扩散动力学，并将其与尾流中的行进入侵前沿相匹配。然后，我们通过在非线性迭代方案中控制这些匹配误差来建立前沿选择，这依赖于对入侵前沿线性化的敏锐估计。我们简要讨论了参数强迫振幅方程、竞争性 Lotka-Volterra 系统和肿瘤生长模型的应用。

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来源期刊

Archive for Rational Mechanics and Analysis 物理-力学

CiteScore

5.10

自引率

8.00%

发文量

审稿时长

4-8 weeks

期刊介绍： The Archive for Rational Mechanics and Analysis nourishes the discipline of mechanics as a deductive, mathematical science in the classical tradition and promotes analysis, particularly in the context of application. Its purpose is to give rapid and full publication to research of exceptional moment, depth and permanence.