Turing patterns on a two-component isotropic growing system. Part 2: Conditions based on a potential function for exponential growth/shrinkage

We propose conditions for the emergence of Turing patterns in a domain that changes in size by homogeneous growth/shrinkage. These conditions to determine the bifurcation are based on considering the geometric change of a potential function whose evolution determines the stability of the trajectories of all the Fourier modes of the perturbation. For this part of the work we consider the situation where the homogeneous state of the system are constant concentrations close to its stationary value, as occurs for exponential growth/decrease. This proposal recovers the traditional Turing conditions for two-component systems in a fixed domain and is corroborated against numerical simulations of increasing/decreasing domains of the Brusselator reaction system. The simulations carried out allowed us to understand some characteristics of the pattern related to the evolution of its amplitude and wavenumber and allow us to anticipate which features strictly depend on its temporal evolution.