Noise is ubiquitous in a system and can induce some spontaneous pattern formations on a spatially homogeneous domain. In comparison to the Reaction-Diffusion System (RDS), Stochastic Reaction-Diffusion System (SRDS) is more complex and it is very difficult to deal with the noise function. In this paper, we have presented a method to solve it and obtained the conditions of how the Turing bifurcation and Hopf bifurcation arise through linear stability analysis of local equilibrium. In addition, we have developed the amplitude equation with a pair of wave vector by using Taylor series expansion, multiscaling, and further expansion in powers of small parameter. Our analysis facilitates finding regions of bifurcations and understanding the patte...
PACS. 47.54.+r – Pattern selection; pattern formation. PACS. 82.40.Bj – Oscillations, chaos, and bif...
Many biological patterns, from population densities to animal coat markings, can be thought of as he...
We revisit a homogeneous reaction-diffusion Turing model subject to the Neumann boundary conditions ...
Pattern formation induced by noise is a celebrated phenomenon in diverse reaction-diffusion systems....
The problem with the analysis of noise-induced transitions between patterns in distributed stochasti...
Turing–Hopf instabilities for reaction-diffusion systems provide spatially inhomogeneous time-period...
In this paper, we investigate pattern dynamics with multivariable by using the method of matrix anal...
The reaction diffusion system is one of the important models to describe the objective world. It is ...
Turing suggested that, under certain conditions, chemicals can react and diffuse in such a way as to...
We consider the classical Turing instability in a reaction-diffusion system as the secend part of ou...
Turing suggested that, under certain conditions, chemicals can react and diffuse in such a way as to...
Turing suggested that, under certain conditions, chemicals can react and diffuse in such a way as to...
summary:The paper deals with the issue of self-organization in applied sciences. It is particularly ...
We study a stochastic spatially extended population model with diffusion, where we find the coexiste...
Many biological patterns, from population densities to animal coat markings, can be thought of as he...
PACS. 47.54.+r – Pattern selection; pattern formation. PACS. 82.40.Bj – Oscillations, chaos, and bif...
Many biological patterns, from population densities to animal coat markings, can be thought of as he...
We revisit a homogeneous reaction-diffusion Turing model subject to the Neumann boundary conditions ...
Pattern formation induced by noise is a celebrated phenomenon in diverse reaction-diffusion systems....
The problem with the analysis of noise-induced transitions between patterns in distributed stochasti...
Turing–Hopf instabilities for reaction-diffusion systems provide spatially inhomogeneous time-period...
In this paper, we investigate pattern dynamics with multivariable by using the method of matrix anal...
The reaction diffusion system is one of the important models to describe the objective world. It is ...
Turing suggested that, under certain conditions, chemicals can react and diffuse in such a way as to...
We consider the classical Turing instability in a reaction-diffusion system as the secend part of ou...
Turing suggested that, under certain conditions, chemicals can react and diffuse in such a way as to...
Turing suggested that, under certain conditions, chemicals can react and diffuse in such a way as to...
summary:The paper deals with the issue of self-organization in applied sciences. It is particularly ...
We study a stochastic spatially extended population model with diffusion, where we find the coexiste...
Many biological patterns, from population densities to animal coat markings, can be thought of as he...
PACS. 47.54.+r – Pattern selection; pattern formation. PACS. 82.40.Bj – Oscillations, chaos, and bif...
Many biological patterns, from population densities to animal coat markings, can be thought of as he...
We revisit a homogeneous reaction-diffusion Turing model subject to the Neumann boundary conditions ...