On the linear stability of some finite difference schemes for nonlinear reaction-diffusion models of chemical reaction networks

Nathan Muyinda; Bernard De Baets; Shodhan Rao

doi:10.2478/caim-2018-0016

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On the linear stability of some finite difference schemes for nonlinear reaction-diffusion models of chemical reaction networks

Communications in Applied and Industrial Mathematics

Volume 9 (2018): Issue 1 (February 2018)

By: Nathan Muyinda, Bernard De Baets and Shodhan Rao

Open Access

|Dec 2018

Abstract

We identify sufficient conditions for the stability of some well-known finite difference schemes for the solution of the multivariable reaction-diffusion equations that model chemical reaction networks. Since the equations are mainly nonlinear, these conditions are obtained through local linearization. A recurrent condition is that the Jacobian matrix of the reaction part evaluated at some positive unknown solution is either D-semi-stable or semi-stable. We demonstrate that for a single reversible chemical reaction whose kinetics are monotone, the Jacobian matrix is D-semi-stable and therefore such schemes are guaranteed to work well.

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Articles in this issue

DOI: https://doi.org/10.2478/caim-2018-0016 | Journal eISSN: 2038-0909

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Language: English

Page range: 121 - 140

Submitted on: Oct 3, 2017

Accepted on: Oct 8, 2018

Published on: Dec 5, 2018

Published by: Italian Society for Applied and Industrial Mathemathics

In partnership with: Paradigm Publishing Services

Publication frequency: 1 issue per year

Keywords:

Reaction-diffusion equations,

Finite difference method,

Stability,

Amplification matrix,

Linearization,

Monotone kinetics

Related subjects:

Mathematics,

Numerical and computational mathematics,

Applied mathematics

© 2018 Nathan Muyinda, Bernard De Baets, Shodhan Rao, published by Italian Society for Applied and Industrial Mathemathics
This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 License.

Volume 9 (2018): Issue 1 (February 2018)