From the simple reacting sphere kinetic model to the reaction-diffusion system of Maxwell-Stefan type

In this paper we perform a formal asymptotic analysis on a kinetic model for reactive mixtures in order to derive a reaction-diffusion system of Maxwell-Stefan type. More specifically, we start from the kinetic model of simple reacting spheres for a quaternary mixture of monatomic ideal gases that u...

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Bibliographic Details
Main Author: Anwasia, Benjamin (author)
Other Authors: Gonçalves, Patrícia (author), Soares, A. J. (author)
Format: article
Language:eng
Published: 2019
Subjects:
Boltzmann-type equations
Chemically reactive mixtures
Diffusion limit
Kinetic theory of gases
Maxwell-Stefan equations
Ciências Naturais::Matemáticas
Science & Technology
Online Access:http://hdl.handle.net/1822/58224
Country:Portugal
Oai:oai:repositorium.sdum.uminho.pt:1822/58224
Description
Summary:In this paper we perform a formal asymptotic analysis on a kinetic model for reactive mixtures in order to derive a reaction-diffusion system of Maxwell-Stefan type. More specifically, we start from the kinetic model of simple reacting spheres for a quaternary mixture of monatomic ideal gases that undergoes a reversible chemical reaction of bimolecular type. Then, we consider a scaling describing a physical situation in which mechanical collisions play a dominant role in the evolution process, while chemical reactions are slow, and compute explicitly the production terms associated to the concentration and momentum balance equations for each species in the reactive mixture. Finally, we prove that, under the isothermal assumption, the limit equations for the scaled kinetic model is the reaction diffusion system of Maxwell-Stefan type.

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