Turing pattern outside of the Turing domain

被引:5
|
作者
Flach, E. H.
Schnell, S.
Norbury, J.
机构
[1] Indiana Univ, Sch Informat, Complex Syst Grp, Bloomington, IN 47406 USA
[2] Math Inst, Ctr Math Biol, Oxford OX1 3LB, England
来源
APPLIED MATHEMATICS LETTERS | 2007年 / 20卷 / 09期
关键词
reaction-diffusion; limit cycle; Schnakenberg; Turing pattern; convection;
D O I
10.1016/j.aml.2006.09.009
中图分类号
O29 [应用数学];
学科分类号
070104 ;
摘要
There are two simple solutions to reaction-diffusion systems with limit-cycle reaction kinetics, producing oscillatory behaviour. The reaction parameter mu gives rise to a 'space-invariant' solution, and mu versus the ratio of the diffusion coefficients gives rise to a time-invariant' solution. We consider the case where both solution types may be possible. This leads to a refinement of the Turing model of pattern formation. We add convection to the system and investigate its effect. More complex solutions arise that appear to combine the two simple solutions. The convective system sheds light on the underlying behaviour of the diffusive system. (C) 2007 Elsevier Ltd. All rights reserved.
引用
收藏
页码:959 / 963
页数:5
相关论文
共 50 条
  • [31] Turing pattern of an SIRI model on large-scale homogeneous and heterogeneous networks
    Le He
    Haijun Su
    Nonlinear Dynamics, 2023, 111 : 16605 - 16626
  • [32] Turing Instabilities at Hopf Bifurcation
    M. R. Ricard
    S. Mischler
    Journal of Nonlinear Science, 2009, 19 : 467 - 496
  • [33] Turing pattern dynamics in a fractional-diffusion oregonator model under PD control
    Li, Hongliang
    Yao, Yi
    Xiao, Min
    Wang, Zhen
    Rutkowski, Leszek
    NONLINEAR ANALYSIS-MODELLING AND CONTROL, 2025, 30 (02): : 291 - 311
  • [34] Dichotomous-noise-induced Turing pattern formation in a predator-prey model
    Lai, Ting
    Yuan, Quan
    Zhang, Jingwen
    Wang, Haohua
    CHINESE JOURNAL OF PHYSICS, 2024, 89 : 1803 - 1818
  • [35] Turing patterns of Gierer–Meinhardt model on complex networks
    Luyao Guo
    Xinli Shi
    Jinde Cao
    Nonlinear Dynamics, 2021, 105 : 899 - 909
  • [36] After 1952: The later development of Alan Turing's ideas on the mathematics of pattern formation
    Dawes, Jonathan H. P.
    HISTORIA MATHEMATICA, 2016, 43 (01) : 49 - 64
  • [37] An updated kernel-based Turing model for studying the mechanisms of biological pattern formation
    Kondo, Shigeru
    JOURNAL OF THEORETICAL BIOLOGY, 2017, 414 : 120 - 127
  • [38] From Homogeneity to Turing Pattern: Kinetically Controlled Self-Organization of Transmembrane Protein
    Lee, Wonhee John
    Kim, Soo Jin
    Ahn, Yongdeok
    Park, Jiseong
    Jin, Siwoo
    Jang, Juhee
    Jeong, Jinju
    Park, Minsoo
    Lee, Young-Sam
    Lee, Junyeop
    Seo, Daeha
    NANO LETTERS, 2024, 24 (06) : 1882 - 1890
  • [39] On the Control of the Microresonator Optical Frequency Comb in Turing Pattern Regime via Parametric Seeding
    Wang, Jinghao
    Zhang, Minming
    Li, Meifeng
    Wang, Yuanwu
    Liu, Deming
    2016 21ST OPTOELECTRONICS AND COMMUNICATIONS CONFERENCE (OECC) HELD JOINTLY WITH 2016 INTERNATIONAL CONFERENCE ON PHOTONICS IN SWITCHING (PS), 2016,
  • [40] Turing pattern of a diffusive predator-prey model with nonlocal delay and herd behavior
    Peng, Yahong
    Yu, Ke
    JOURNAL OF MATHEMATICAL ANALYSIS AND APPLICATIONS, 2023, 527 (01)
12345