Abstract
Generalized mass-action systems are power-law dynamical systems arising from chemical reaction networks. Essentially, every nonnegative ODE model used in chemistry and biology (for example, in ecology and epidemiology) and even in economics and engineering can be written in this form. Previous results have focused on existence and uniqueness of special steady states (complex-balanced equilibria) for all rate constants, thereby ruling out multiple (special) steady states. Recently, necessary conditions for linear stability have been obtained. In this work, we provide sufficient conditions for the linear stability of complex-balanced equilibria for all rate constants (and also for the nonexistence of other steady states). In particular, via sign vector conditions (on the stoichiometric coefficients and kinetic orders), we guarantee that the Jacobian matrix is a P-matrix. Technically, we use a new decomposition of the graph Laplacian which allows us to consider orders of (generalized) monomials. Alternatively, we use cycle decomposition which allows a linear parametrization of all Jacobian matrices. In any case, we guarantee stability without explicit computation of steady states. We illustrate our results in examples from chemistry and biology: generalized Lotka-Volterra systems and SIR models, a two-component signaling system, and an enzymatic futile cycle.
Original language | English |
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Pages (from-to) | 325-357 |
Number of pages | 33 |
Journal | SIAM Journal on Applied Dynamical Systems |
Volume | 23 |
Issue number | 1 |
Early online date | 22 Jan 2024 |
DOIs | |
Publication status | Published - 2024 |
Austrian Fields of Science 2012
- 101027 Dynamical systems
Keywords
- chemical reaction networks
- generalized mass-action kinetics
- P-matrix
- polynomial/power-law dynamical systems
- stability