Today I read a paper titled “Simple and Superlattice Turing Patterns in Reaction-Diffusion Systems: Bifurcation, Bistability, and Parameter Collapse”
The abstract is:
This paper investigates the competition between both simple (e.g.
stripes, hexagons) and “superlattice” (super squares, super hexagons) Turing patterns in two-component reaction-diffusion systems.
“Superlattice” patterns are formed from eight or twelve Fourier modes, and feature structure at two different length scales.
Using perturbation theory, we derive simple analytical expressions for the bifurcation equation coefficients on both rhombic and hexagonal lattices.
These expressions show that, no matter how complicated the reaction kinectics, the nonlinear reaction terms reduce to just four effective terms within the bifurcation equation coefficients.
Moreover, at the hexagonal degeneracy — when the quadratic term in the hexagonal bifurcation equation disappears — the number of effective system parameters drops to two, allowing a complete characterization of the possible bifurcation results at this degeneracy.
The general results are then applied to specific model equations, to investigate the stability of different patterns within those models.