Turing Instability for Nonlocal Heterogeneous Reaction-Diffusion Systems: A Computer-Assisted Proof Approach

Maxime Payan; Maxime Breden; Cordula Reisch; Bao Quoc Tang

doi:10.1007/s10884-026-10488-0

Turing Instability for Nonlocal Heterogeneous Reaction-Diffusion Systems: A Computer-Assisted Proof Approach

Maxime Payan
, Maxime Breden
, Cordula Reisch
, Bao Quoc Tang

Research output: Contribution to journal › Article › peer-review

Abstract

This paper provides a computer-assisted proof for the Turing instability induced by heterogeneous nonlocality in reaction-diffusion systems. Due to the heterogeneity and nonlocality, the linear Fourier analysis gives rise to strongly coupled infinite differential systems. By introducing suitable changes of basis as well as the Gershgorin disks theorem for infinite matrices, we first show that all N-th Gershgorin disks lie completely on the left half-plane for sufficiently large N. For the remaining finitely many disks, a computer-assisted proof shows that if the intensity δ of the nonlocal term is large enough, there is precisely one eigenvalue with positive real part, which proves the Turing instability. Moreover, by a detailed study of this eigenvalue as a function of δ, we obtain a sharp threshold δ∗ which is the bifurcation point for Turing instability.

Original language	English
Journal	Journal of Dynamics and Differential Equations
DOIs	https://doi.org/10.1007/s10884-026-10488-0
Publication status	Accepted/In press - 1 Jan 2026

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title = "Turing Instability for Nonlocal Heterogeneous Reaction-Diffusion Systems: A Computer-Assisted Proof Approach",

abstract = "This paper provides a computer-assisted proof for the Turing instability induced by heterogeneous nonlocality in reaction-diffusion systems. Due to the heterogeneity and nonlocality, the linear Fourier analysis gives rise to strongly coupled infinite differential systems. By introducing suitable changes of basis as well as the Gershgorin disks theorem for infinite matrices, we first show that all N-th Gershgorin disks lie completely on the left half-plane for sufficiently large N. For the remaining finitely many disks, a computer-assisted proof shows that if the intensity δ of the nonlocal term is large enough, there is precisely one eigenvalue with positive real part, which proves the Turing instability. Moreover, by a detailed study of this eigenvalue as a function of δ, we obtain a sharp threshold δ∗ which is the bifurcation point for Turing instability.",

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T2 - A Computer-Assisted Proof Approach

AU - Payan, Maxime

AU - Breden, Maxime

AU - Reisch, Cordula

AU - Tang, Bao Quoc

N1 - Publisher Copyright: © The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature 2026.

PY - 2026/1/1

Y1 - 2026/1/1

N2 - This paper provides a computer-assisted proof for the Turing instability induced by heterogeneous nonlocality in reaction-diffusion systems. Due to the heterogeneity and nonlocality, the linear Fourier analysis gives rise to strongly coupled infinite differential systems. By introducing suitable changes of basis as well as the Gershgorin disks theorem for infinite matrices, we first show that all N-th Gershgorin disks lie completely on the left half-plane for sufficiently large N. For the remaining finitely many disks, a computer-assisted proof shows that if the intensity δ of the nonlocal term is large enough, there is precisely one eigenvalue with positive real part, which proves the Turing instability. Moreover, by a detailed study of this eigenvalue as a function of δ, we obtain a sharp threshold δ∗ which is the bifurcation point for Turing instability.

AB - This paper provides a computer-assisted proof for the Turing instability induced by heterogeneous nonlocality in reaction-diffusion systems. Due to the heterogeneity and nonlocality, the linear Fourier analysis gives rise to strongly coupled infinite differential systems. By introducing suitable changes of basis as well as the Gershgorin disks theorem for infinite matrices, we first show that all N-th Gershgorin disks lie completely on the left half-plane for sufficiently large N. For the remaining finitely many disks, a computer-assisted proof shows that if the intensity δ of the nonlocal term is large enough, there is precisely one eigenvalue with positive real part, which proves the Turing instability. Moreover, by a detailed study of this eigenvalue as a function of δ, we obtain a sharp threshold δ∗ which is the bifurcation point for Turing instability.

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Turing Instability for Nonlocal Heterogeneous Reaction-Diffusion Systems: A Computer-Assisted Proof Approach

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