The Turing reaction–diffusion model [Phil. Trans. R. Soc. 237 (1952) 37–72] for self-organised spatial pattern formation has been the subject of a great deal of study for the case of spatially homogeneous parameters. The case of parameters which vary spatially has received less attention. Here, we show that a simple step function heterogeneity in a kinetic parameter can lead to spatial pattern formation outside the classical Turing space parameter regime for patterning. This reduces the constraints on the model parameters, extending possible applications. Furthermore, it highlights the potential importance of boundaries during pattern formation
AbstractReaction-diffusion, or Turing, models have been proposed to account for a number of pattern ...
Pattern formation from homogeneity is well-studied, but less is known concerning symmetry-breaking i...
Pattern formation from homogeneity is well studied, but less is known concerning symmetry-breaking i...
The Turing reaction–diffusion model [Phil. Trans. R. Soc. 237 (1952) 37–72] for self-organised spati...
The Turing reaction–diffusion model [Phil. Trans. R. Soc. 237 (1952) 37–72] for self-organised spati...
Reaction-diffusion, or Turing, models have been proposed to account for a number of pattern formatio...
Reaction-diffusion, or Turing, models have been proposed to account for a number of pattern formatio...
AbstractReaction-diffusion, or Turing, models have been proposed to account for a number of pattern ...
Recent examples of biological pattern formation where a pattern changes qualitatively as the underly...
Recent examples of biological pattern formation where a pattern changes qualitatively as the underly...
Recent examples of biological pattern formation where a pattern changes qualitatively as the underly...
Recent examples of biological pattern formation where a pattern changes qualitatively as the underly...
Recent examples of biological pattern formation where a pattern changes qualitatively as the underly...
Spontaneous pattern formation in reaction–diffusion systems on a spatially homogeneous domain has be...
Recent examples of biological pattern formation where a pattern changes qual-itatively as the underl...
AbstractReaction-diffusion, or Turing, models have been proposed to account for a number of pattern ...
Pattern formation from homogeneity is well-studied, but less is known concerning symmetry-breaking i...
Pattern formation from homogeneity is well studied, but less is known concerning symmetry-breaking i...
The Turing reaction–diffusion model [Phil. Trans. R. Soc. 237 (1952) 37–72] for self-organised spati...
The Turing reaction–diffusion model [Phil. Trans. R. Soc. 237 (1952) 37–72] for self-organised spati...
Reaction-diffusion, or Turing, models have been proposed to account for a number of pattern formatio...
Reaction-diffusion, or Turing, models have been proposed to account for a number of pattern formatio...
AbstractReaction-diffusion, or Turing, models have been proposed to account for a number of pattern ...
Recent examples of biological pattern formation where a pattern changes qualitatively as the underly...
Recent examples of biological pattern formation where a pattern changes qualitatively as the underly...
Recent examples of biological pattern formation where a pattern changes qualitatively as the underly...
Recent examples of biological pattern formation where a pattern changes qualitatively as the underly...
Recent examples of biological pattern formation where a pattern changes qualitatively as the underly...
Spontaneous pattern formation in reaction–diffusion systems on a spatially homogeneous domain has be...
Recent examples of biological pattern formation where a pattern changes qual-itatively as the underl...
AbstractReaction-diffusion, or Turing, models have been proposed to account for a number of pattern ...
Pattern formation from homogeneity is well-studied, but less is known concerning symmetry-breaking i...
Pattern formation from homogeneity is well studied, but less is known concerning symmetry-breaking i...
Add to ORKG