Boundedness of Solution for the Chemotaxis Model with Indirect Signal Absorption and Logistic Source

In this paper, we focus on the qualitative analysis of a parabolic–elliptic attraction–repulsion chemotaxis model with logistic source. Applying a fixed point argument, [Formula: see text]-estimate technique and Moser’s iteration, we derive that the model admits a unique global solution provided the initial cell mass satisfying [Formula: see text] for [Formula: see text] While for [Formula: see text], there are no restrictions on the initial cell mass and the result still holds.

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Asymptotic stability in a fully parabolic quasilinear chemotaxis model with general logistic source and signal production

Journal of Differential Equations ◽

10.1016/j.jde.2019.11.052 ◽

2020 ◽

Vol 268 (11) ◽

pp. 6729-6777 ◽

Cited By ~ 5

Author(s):

Mengyao Ding ◽

Wei Wang ◽

Shulin Zhou ◽

Sining Zheng

Keyword(s):

Asymptotic Stability ◽

Logistic Source ◽

Chemotaxis Model ◽

Signal Production

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A quasilinear parabolic-parabolic chemotaxis model with logistic source and singular sensitivity

Discrete & Continuous Dynamical Systems - B ◽

10.3934/dcdsb.2021193 ◽

2021 ◽

Vol 0 (0) ◽

pp. 0

Author(s):

Jie Zhao

Keyword(s):

Boundary Conditions ◽

Positive Constant ◽

Smooth Boundary ◽

Neumann Boundary ◽

Logistic Source ◽

Chemotaxis Model ◽

Singular Sensitivity ◽

Dynamical Properties ◽

Chemotaxis System ◽

Quasilinear Parabolic

This paper deals with the dynamical properties of the quasilinear parabolic-parabolic chemotaxis system<disp-formula> <label/> <tex-math id="FE1"> \begin{document}$ \begin{eqnarray*} \left\{ \begin{array}{llll} u_{t} = \nabla\cdot(D(u)\nabla u)-\chi\nabla\cdot(\frac{u}{v} \nabla v)+\mu u- \mu u^{2}, \, \, \, &x\in\Omega, \, \, \, t>0, \\ v_{t} = \Delta v-v+u, &x\in\Omega, \, \, \, t>0, \end{array} \right. \end{eqnarray*} $\end{document} </tex-math></disp-formula>under homogeneous Neumann boundary conditions in a convex bounded domain <inline-formula><tex-math id="M1">\begin{document}$ \Omega\subset\mathbb{R}^{n} $\end{document}</tex-math></inline-formula>, <inline-formula><tex-math id="M2">\begin{document}$ n\geq2 $\end{document}</tex-math></inline-formula>, with smooth boundary. <inline-formula><tex-math id="M3">\begin{document}$ \chi>0 $\end{document}</tex-math></inline-formula> and <inline-formula><tex-math id="M4">\begin{document}$ \mu>0 $\end{document}</tex-math></inline-formula>, <inline-formula><tex-math id="M5">\begin{document}$ D(u) $\end{document}</tex-math></inline-formula> is supposed to satisfy the behind properties<disp-formula> <label/> <tex-math id="FE2"> \begin{document}$ \begin{equation*} \begin{split} D(u)\geq (u+1)^{\alpha} \, \, \, \text{with}\, \, \, \alpha>0. \end{split} \end{equation*} $\end{document} </tex-math></disp-formula>It is shown that there is a positive constant <inline-formula><tex-math id="M6">\begin{document}$ m_{*} $\end{document}</tex-math></inline-formula> such that<disp-formula> <label/> <tex-math id="FE3"> \begin{document}$ \begin{equation*} \begin{split} \int_{\Omega}u\geq m_{*} \end{split} \end{equation*} $\end{document} </tex-math></disp-formula>for all <inline-formula><tex-math id="M7">\begin{document}$ t\geq0 $\end{document}</tex-math></inline-formula>. Moreover, we prove that the solution is globally bounded. Finally, it is asserted that the solution exponentially converges to the constant stationary solution <inline-formula><tex-math id="M8">\begin{document}$ (1, 1) $\end{document}</tex-math></inline-formula>.

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