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Chemotaxis systems with singular sensitivity and logistic source: Boundedness, persistence, absorbing set, and entire solutions

Halil Ibrahim Kurt, Wenxian Shen

Abstract

This paper deals with the following parabolic-elliptic chemotaxis system with singular sensitivity and logistic source, \begin{equation} \begin{cases} u_t=Δu-χ\nabla\cdot (\frac{u}{v} \nabla v)+u(a(t,x)-b(t,x) u), & x\in Ω,\cr 0=Δv- μv+ νu, & x\in Ω, \cr \frac{\partial u}{\partial n}=\frac{\partial v}{\partial n}=0, & x\in\partialΩ, \end{cases} \end{equation} where $Ω\subset \mathbb{R}^N$ is a smooth bounded domain, $a(t,x)$ and $b(t,x)$ are positive smooth functions, and $χ$, $μ$ and $ν$ are positive constants. In the very recent paper [25], we proved that for given nonnegative initial function $0\not\equiv u_0\in C^0(\bar Ω)$ and $s\in\mathbb{R}$, (0.1) has a unique globally defined classical solution $(u(t,x;s,u_0),v(t,x;s,u_0))$ with $u(s,x;s,u_0)=u_0(x)$, provided that $a_{\inf}=\inf_{t\in\mathbb{R},x\inΩ}a(t,x)$ is large relative to $χ$ and $u_0$ is not small. In this paper, we further investigate qualitative properties of globally defined positive solutions of (0.1) under the assumption that $a_{\inf}$ is large relative to $χ$ and $u_0$ is not small. Among others, we provide some concrete estimates for $\int_Ωu^{-p}$ and $\int_Ωu^q$ for some $p>0$ and $q>\max\{2,N\}$ and prove that any globally defined positive solution is bounded above and below eventually by some positive constants independent of its initial functions. We prove the existence of a ``rectangular'' type bounded invariant set (in $L^q$) which eventually attracts all the globally defined positive solutions. We also prove that (0.1) has a positive entire classical solution $(u^*(t,x),v^*(t,x))$, which is periodic in $t$ if $a(t,x)$ and $b(t,x)$ are periodic in $t$ and is independent of $t$ if $a(t,x)$ and $b(t,x)$ are independent of $t$.

Chemotaxis systems with singular sensitivity and logistic source: Boundedness, persistence, absorbing set, and entire solutions

Abstract

This paper deals with the following parabolic-elliptic chemotaxis system with singular sensitivity and logistic source, \begin{equation} \begin{cases} u_t=Δu-χ\nabla\cdot (\frac{u}{v} \nabla v)+u(a(t,x)-b(t,x) u), & x\in Ω,\cr 0=Δv- μv+ νu, & x\in Ω, \cr \frac{\partial u}{\partial n}=\frac{\partial v}{\partial n}=0, & x\in\partialΩ, \end{cases} \end{equation} where is a smooth bounded domain, and are positive smooth functions, and , and are positive constants. In the very recent paper [25], we proved that for given nonnegative initial function and , (0.1) has a unique globally defined classical solution with , provided that is large relative to and is not small. In this paper, we further investigate qualitative properties of globally defined positive solutions of (0.1) under the assumption that is large relative to and is not small. Among others, we provide some concrete estimates for and for some and and prove that any globally defined positive solution is bounded above and below eventually by some positive constants independent of its initial functions. We prove the existence of a ``rectangular'' type bounded invariant set (in ) which eventually attracts all the globally defined positive solutions. We also prove that (0.1) has a positive entire classical solution , which is periodic in if and are periodic in and is independent of if and are independent of .
Paper Structure (6 sections, 20 theorems, 158 equations)

This paper contains 6 sections, 20 theorems, 158 equations.

Key Result

Proposition 1.1

(Local existence) For any $s\in\mathbb{R}$ and $u_0$ satisfying initial-cond-eq, there is $T_{\max}(s,u_0)\in (0,\infty]$ such that the system main-eq possesses a unique classical solution, denoted by $(u(t,x;s,u_0)$, $v(t,x;s,u_0))$, on $(s,T_{\max}(s,u_0))$ with initial condition $u(s,x;s,u_0)=u_0

Theorems & Definitions (44)

  • Definition 1.1
  • Proposition 1.1
  • Theorem 1.1: Boundedness of $\int_\Omega u^{-p}$ and $\int_\Omega u^q$
  • Remark 1.1
  • Theorem 1.2: Globally absorbing rectangle
  • Remark 1.2
  • Theorem 1.3: Uniform pointwise persistence
  • Remark 1.3
  • Theorem 1.4: Existence of positive entire solutions
  • Remark 1.4
  • ...and 34 more