Saved in:
Bibliographic Details
Main Authors: Wu, Qidong, Yi, Fengqi
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2412.15531
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866916535361077248
author Wu, Qidong
Yi, Fengqi
author_facet Wu, Qidong
Yi, Fengqi
contents Spatiotemporal pattern formations in two-layer coupled reaction-diffusion Lengyel-Epstein system with distributed delayed couplings are investigated. Firstly, for the original decoupled system, it is proved that when the intra-reactor diffusion rate $\ep$ of the inhibitor is sufficiently small and the intra-reactor diffusion rate $d$ of the inhibitor is large enough, then the subsystem can exhibit non-constant positive steady state $(\widetilde{u}(x;\ep),\widetilde{v}(x;ε))$ with large amplitude, and that as the parameter $τ$ varies, the stability of $(\widetilde{u}(x;\ep),\widetilde{v}(x;ε))$ changes, leading to the emergence of periodic solutions via Hopf bifurcation. Secondly, for the two-layer coupled system, the stability of the symmetric steady state $(\widetilde{u}(x;\ep),\widetilde{v}(x;ε),\widetilde{u}(x;\ep),\widetilde{v}(x;ε))$ is studied by treating $k_1,k_2$ (the inter-reactor diffusion rates) and $\al$ (the delay parameter) as the main parameters. In case of non-delayed couplings, the first quadrant of the $(k_1, k_2)$ parameter space can be divided into two regions: one is stable region, the other one is unstable region, and the two regions have the common boundary, which is the primary Turing bifurcation curve. In case of delayed couplings, it is shown that the first quadrant of the $(k_1, k_2)$ parameter space can be re-divided into three regions: the first one is unstable region, the second one is stable region, while the third one is the potential \lq\lq bifurcation\rq\rq region, where Hopf bifurcation may occur for suitable $\al$. Our analysis is mainly based on the singular perturbation techniques and the implicit function theorem, and the results show some different phenomena from those of the original decoupled system in one reactor.
format Preprint
id arxiv_https___arxiv_org_abs_2412_15531
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Spatiotemporal pattern formations in a two-layer coupled reaction-diffusion Lengyel-Epstein system
Wu, Qidong
Yi, Fengqi
Analysis of PDEs
35B32, 35P20, 35Q92, 92E20
Spatiotemporal pattern formations in two-layer coupled reaction-diffusion Lengyel-Epstein system with distributed delayed couplings are investigated. Firstly, for the original decoupled system, it is proved that when the intra-reactor diffusion rate $\ep$ of the inhibitor is sufficiently small and the intra-reactor diffusion rate $d$ of the inhibitor is large enough, then the subsystem can exhibit non-constant positive steady state $(\widetilde{u}(x;\ep),\widetilde{v}(x;ε))$ with large amplitude, and that as the parameter $τ$ varies, the stability of $(\widetilde{u}(x;\ep),\widetilde{v}(x;ε))$ changes, leading to the emergence of periodic solutions via Hopf bifurcation. Secondly, for the two-layer coupled system, the stability of the symmetric steady state $(\widetilde{u}(x;\ep),\widetilde{v}(x;ε),\widetilde{u}(x;\ep),\widetilde{v}(x;ε))$ is studied by treating $k_1,k_2$ (the inter-reactor diffusion rates) and $\al$ (the delay parameter) as the main parameters. In case of non-delayed couplings, the first quadrant of the $(k_1, k_2)$ parameter space can be divided into two regions: one is stable region, the other one is unstable region, and the two regions have the common boundary, which is the primary Turing bifurcation curve. In case of delayed couplings, it is shown that the first quadrant of the $(k_1, k_2)$ parameter space can be re-divided into three regions: the first one is unstable region, the second one is stable region, while the third one is the potential \lq\lq bifurcation\rq\rq region, where Hopf bifurcation may occur for suitable $\al$. Our analysis is mainly based on the singular perturbation techniques and the implicit function theorem, and the results show some different phenomena from those of the original decoupled system in one reactor.
title Spatiotemporal pattern formations in a two-layer coupled reaction-diffusion Lengyel-Epstein system
topic Analysis of PDEs
35B32, 35P20, 35Q92, 92E20
url https://arxiv.org/abs/2412.15531