Conditions for spatial instabilities and pattern formation from monomial steady state parameterizations
Abstract
We study the onset of spatial instabilities in reaction networks where the spatially homogeneous system admits a steady state parameterization. We formulate a sufficient condition -- based on the signs of the constant and leading coefficients of the characteristic polynomial of the linearized Jacobian scaled by the diffusion coefficients -- that guarantees a Turing-like instability to spatially inhomogeneous solutions on appropriately chosen domains . We also present a specific condition on the domain size required to trigger this instability. As a consequence of employing a monomial parameterization, these conditions take the form of algebraic polynomial inequalities involving only rate constants and diffusion coefficients. We apply these ideas to a network describing the sequential and distributive (de-)phosphorylation of a protein at two binding sites, ultimately deriving a condition involving only the four catalytic constants of the enzymes and the diffusion coefficients of the four enzyme-substrate complexes that guarantees a Turing-like instability.
Cite
@article{arxiv.2605.16049,
title = {Conditions for spatial instabilities and pattern formation from monomial steady state parameterizations},
author = {Carsten Conradi and Maya Mincheva and Hannes Uecker},
journal= {arXiv preprint arXiv:2605.16049},
year = {2026}
}