APPLICATION OF THE SEMIGROUP THEORY TO A COMBUSTION PROBLEM IN A MULTI-LAYER POROUS MEDIUM

IF 1 4区数学 Q3 MATHEMATICS, APPLIED Journal of Applied Analysis and Computation Pub Date : 2023-01-01 DOI:10.11948/20220333

Eduardo A. Alarcon, Marcos R. Batista, Alysson Cunha, Jesus C. Da Mota, Ronaldo A. Santos

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引用次数: 1

Abstract

This study proved that the Cauchy problem for a one-dimensional reaction-diffusion-convection system is locally and globally well-posed in $ \mathtt{H}^2(\mathbb{R})$. The system modeled a gasless combustion front through a multi-layer porous medium when the fuel concentration in each layer was a known function. Combustion has critical practical porous media applications, such as in in-situ combustion processes in oil reservoirs and several other areas. Earlier studies considered physical parameters (e.g., porosity, thermal conductivity, heat capacity, and initial fuel concentration) constant. Here, we consider a more realistic model where these parameters are functions of the spatial variable rather than constants. Furthermore, in previous studies, we did not consider the continuity of the solution regarding the initial data and parameters, unlike the current study. This proof uses a novel approach to combustion problems in porous media. We follow the abstract semigroups theory of operators in the Hilbert space and the well-known Kato's theory for a well-posed associated initial value problem.

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半群理论在多层多孔介质燃烧问题中的应用

本文证明了一维反应-扩散-对流系统的Cauchy问题在$ \mathtt{H}^2(\mathbb{R})$中是局部和全局良定的。该系统模拟了多层多孔介质中每层燃料浓度为已知函数时的无气体燃烧前沿。燃烧具有重要的实际多孔介质应用，例如油藏和其他一些领域的原位燃烧过程。早期的研究认为物理参数(如孔隙度、导热性、热容和初始燃料浓度)是恒定的。在这里，我们考虑一个更现实的模型，其中这些参数是空间变量的函数，而不是常量。此外，在之前的研究中，我们没有考虑初始数据和参数的解的连续性，这与当前的研究不同。这个证明使用了一种新的方法来研究多孔介质中的燃烧问题。我们采用Hilbert空间中算子的抽象半群理论和著名的Kato理论来求解一类适定关联初值问题。

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来源期刊

Journal of Applied Analysis and Computation MATHEMATICS, APPLIED-

CiteScore

2.30

自引率

9.10%

发文量

期刊介绍： The Journal of Applied Analysis and Computation (JAAC) is aimed to publish original research papers and survey articles on the theory, scientific computation and application of nonlinear analysis, differential equations and dynamical systems including interdisciplinary research topics on dynamics of mathematical models arising from major areas of science and engineering. The journal is published quarterly in February, April, June, August, October and December by Shanghai Normal University and Wilmington Scientific Publisher, and issued by Shanghai Normal University.