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Main Authors: Matano, Hiroshi, Jimbo, Shuichi
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.24418
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author Matano, Hiroshi
Jimbo, Shuichi
author_facet Matano, Hiroshi
Jimbo, Shuichi
contents We consider a bistable reaction-diffusion equation on a metric graph that is a generalization of the so-called star graphs. More precisely, our graph $Ω$ consists of a bounded finite metric graph $D$ of arbitrary configuration and a finite number of branches $Ω_1,\ldots,Ω_N\,(N\geq 2)$ of infinite length emanating from some of the vertices of $D$. Each $Ω_i\,(i=1,\ldots,N)$ is called an ``outer path''. Our goal is to investigate the behavior of the front coming from infinity along a given outer path $Ω_i$ and to discuss whether or not the front propagates into other outer paths $Ω_j\,(j\ne i)$. Unlike the case of star graphs, where $D$ is a single vertex, the dynamics of solutions can be far more complex and may depend sensitively on the configuration of the center graph $D$. We first focus on general principles that hold regardless of the structure of the center graph $D$. Among other things, we introduce the notion ``limit profile'', which allows us to define ``propagation'' and ``blocking'' without ambiguity, then we prove transient properties, that is, propagation $Ω_i\to Ω_j$ and $Ω_j\to Ω_k$ imply propagation $Ω_i\to Ω_k$. Next we consider perturbations of the graph $D$ while fixing the outer paths $Ω_1,\ldots,Ω_N$ and prove that if, for a given choice of $i,j$, propagation $Ω_i\to Ω_j$ occurs for a graph $D$, then the same holds for any graph $D'$ that is sufficiently close to $D$ (robustness under perturbation). We also consider several specific classes of graphs, such as those with a ``reservoir'' type subgraph, and study their intriguing properties.
format Preprint
id arxiv_https___arxiv_org_abs_2505_24418
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Front propagation on a general metric graph
Matano, Hiroshi
Jimbo, Shuichi
Analysis of PDEs
35R02, 35K57, 35K58, 35C07, 35B08
We consider a bistable reaction-diffusion equation on a metric graph that is a generalization of the so-called star graphs. More precisely, our graph $Ω$ consists of a bounded finite metric graph $D$ of arbitrary configuration and a finite number of branches $Ω_1,\ldots,Ω_N\,(N\geq 2)$ of infinite length emanating from some of the vertices of $D$. Each $Ω_i\,(i=1,\ldots,N)$ is called an ``outer path''. Our goal is to investigate the behavior of the front coming from infinity along a given outer path $Ω_i$ and to discuss whether or not the front propagates into other outer paths $Ω_j\,(j\ne i)$. Unlike the case of star graphs, where $D$ is a single vertex, the dynamics of solutions can be far more complex and may depend sensitively on the configuration of the center graph $D$. We first focus on general principles that hold regardless of the structure of the center graph $D$. Among other things, we introduce the notion ``limit profile'', which allows us to define ``propagation'' and ``blocking'' without ambiguity, then we prove transient properties, that is, propagation $Ω_i\to Ω_j$ and $Ω_j\to Ω_k$ imply propagation $Ω_i\to Ω_k$. Next we consider perturbations of the graph $D$ while fixing the outer paths $Ω_1,\ldots,Ω_N$ and prove that if, for a given choice of $i,j$, propagation $Ω_i\to Ω_j$ occurs for a graph $D$, then the same holds for any graph $D'$ that is sufficiently close to $D$ (robustness under perturbation). We also consider several specific classes of graphs, such as those with a ``reservoir'' type subgraph, and study their intriguing properties.
title Front propagation on a general metric graph
topic Analysis of PDEs
35R02, 35K57, 35K58, 35C07, 35B08
url https://arxiv.org/abs/2505.24418