Fractal Fract, Vol. 9, Pages 803: On the Stability of Incommensurate Fractional-Order Reaction–Diffusion Systems: The Glycolyse Model

Fractal and Fractional doi: 10.3390/fractalfract9120803

Authors:
Omar Kahouli
Amel Hioual
Adel Ouannas
Lilia El Amraoui
Mohamed Ayari

In this paper, we study the local stability of an incommensurate fractional reaction–diffusion glycolysis model. The glycolysis process, fundamental to cellular metabolism, exhibits complex dynamical behaviors when formulated as a nonlinear reaction–diffusion system. To capture the heterogeneous memory effects often present in biochemical and chemical processes, we extend the classical model by introducing incommensurate fractional derivatives, where each species evolves with a distinct fractional order. We linearize the system around the positive steady state and derive sufficient conditions for local asymptotic stability by analyzing the eigenvalues of the associated Jacobian matrix under fractional-order dynamics. The results demonstrate how diffusion and non-uniform fractional orders jointly shape the stability domain of the system, highlighting scenarios where diffusion destabilizes homogeneous equilibria and others where incommensurate memory effects enhance stability. Numerical simulations are presented to illustrate and validate the theoretical findings.

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Omar Kahouli www.mdpi.com