On quasi-linear reaction diffusion systems arising from compartmental SEIR models.

IF 1.1 4区数学 Q2 MATHEMATICS, APPLIED Nodea-Nonlinear Differential Equations and Applications Pub Date : 2024-01-01 Epub Date: 2024-08-06 DOI:10.1007/s00030-024-00985-w

Juan Yang, Jeff Morgan, Bao Quoc Tang

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Abstract

The global existence and boundedness of solutions to quasi-linear reaction-diffusion systems are investigated. The system arises from compartmental models describing the spread of infectious diseases proposed in Viguerie et al. (Appl Math Lett 111:106617, 2021); Viguerie et al. (Comput Mech 66(5):1131-1152, 2020), where the diffusion rate is assumed to depend on the total population, leading to quasilinear diffusion with possible degeneracy. The mathematical analysis of this model has been addressed recently in Auricchio et al. (Math Methods Appl Sci 46:12529-12548, 2023) where it was essentially assumed that all sub-populations diffuse at the same rate, which yields a positive lower bound of the total population, thus removing the degeneracy. In this work, we remove this assumption completely and show the global existence and boundedness of solutions by exploiting a recently developed $L^{p}$ -energy method. Our approach is applicable to a larger class of systems and is sufficiently robust to allow model variants and different boundary conditions.

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关于分区 SEIR 模型产生的准线性反应扩散系统。

研究了准线性反应扩散系统解的全局存在性和有界性。该系统源于 Viguerie 等人（Appl Math Lett 111:106617, 2021）和 Viguerie 等人（Comput Mech 66(5):1131-1152, 2020）提出的描述传染病传播的分区模型，其中假定扩散率取决于总人口，从而导致可能存在退化的准线性扩散。最近，Auricchio 等人（Math Methods Appl Sci 46:12529-12548, 2023）对这一模型进行了数学分析，主要假设所有子种群的扩散速率相同，从而得到总种群的正下限，从而消除了退化现象。在这项工作中，我们完全取消了这一假设，并利用最近开发的 L p 能量方法证明了解的全局存在性和有界性。我们的方法适用于更大类别的系统，并具有足够的鲁棒性，允许模型变体和不同的边界条件。

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

Nodea-Nonlinear Differential Equations and Applications 数学-应用数学

CiteScore

1.70

自引率

8.30%

发文量

审稿时长

>12 weeks

期刊介绍： Nonlinear Differential Equations and Applications (NoDEA) provides a forum for research contributions on nonlinear differential equations motivated by application to applied sciences. The research areas of interest for NoDEA include, but are not limited to: deterministic and stochastic ordinary and partial differential equations, finite and infinite-dimensional dynamical systems, qualitative analysis of solutions, variational, topological and viscosity methods, mathematical control theory, complex dynamics and pattern formation, approximation and numerical aspects.