Nonlinear Stability and Asymptotic Behavior of Periodic Wave Trains in Reaction–Diffusion Systems Against \(C_{\textrm{ub}}\)-perturbations

IF 4.6 Q2 MATERIALS SCIENCE, BIOMATERIALS
Björn de Rijk
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引用次数: 0

Abstract

We present a nonlinear stability theory for periodic wave trains in reaction–diffusion systems, which relies on pure \(L^\infty \)-estimates only. Our analysis shows that localization or periodicity requirements on perturbations, as present in the current literature, can be completely lifted. Inspired by previous works considering localized perturbations, we decompose the semigroup generated by the linearization about the wave train and introduce a spatio-temporal phase modulation to capture the most critical dynamics, which is governed by a viscous Burgers’ equation. We then aim to close a nonlinear stability argument by iterative estimates on the corresponding Duhamel formulation, where, hampered by the lack of localization, we must rely on diffusive smoothing to render decay of the semigroup. However, this decay is not strong enough to control all terms in the Duhamel formulation. We address this difficulty by applying the Cole–Hopf transform to eliminate the critical Burgers’-type nonlinearities. Ultimately, we establish nonlinear stability of diffusively spectrally stable wave trains against \(C_{\textrm{ub}}\)-perturbations. Moreover, we show that the perturbed solution converges to a modulated wave train, whose phase and wavenumber are approximated by solutions to the associated viscous Hamilton–Jacobi and Burgers’ equation, respectively.

反应-扩散系统中周期波列在 $$C_{\textrm{ub}}$ -扰动下的非线性稳定性和渐近行为
我们提出了反应扩散系统中周期波列的非线性稳定性理论,该理论仅依赖于纯(L^\infty \)估计。我们的分析表明,现有文献中对扰动的局部性或周期性要求可以完全取消。受之前考虑局部扰动的研究启发,我们分解了由关于波列的线性化产生的半群,并引入时空相位调制来捕捉最关键的动力学,该动力学受粘性布尔格斯方程支配。然后,我们旨在通过对相应的杜哈梅尔公式进行迭代估计来完成非线性稳定性论证,由于缺乏局部性,我们必须依靠扩散平滑来实现半群的衰减。然而,这种衰减并不足以控制杜哈梅尔公式中的所有项。我们通过应用科尔-霍普夫变换来消除临界布尔格斯型非线性,从而解决了这一难题。最终,我们建立了针对 \(C_{textrm{ub}}\) -扰动的扩散谱稳定波列的非线性稳定性。此外,我们还证明了扰动解收敛于调制波列,其相位和波数分别近似于相关粘性汉密尔顿-贾科比方程和布尔格斯方程的解。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
ACS Applied Bio Materials
ACS Applied Bio Materials Chemistry-Chemistry (all)
CiteScore
9.40
自引率
2.10%
发文量
464
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