DYNAMICS FOR A CHEMOTAXIS MODEL WITH GENERAL LOGISTIC DAMPING AND SIGNAL DEPENDENT MOTILITY

doi:10.1007/s10473-024-0316-7

数学物理学报(英文版) ›› 2024, Vol. 44 ›› Issue (3): 1046-1063.doi: 10.1007/s10473-024-0316-7

DYNAMICS FOR A CHEMOTAXIS MODEL WITH GENERAL LOGISTIC DAMPING AND SIGNAL DEPENDENT MOTILITY

Xinyu Tu^1,2, Chunlai Mu^3,*, Shuyan Qiu⁴, Jing Zhang⁵

1. School of Mathematics and Statistics, Southwest University, Chongqing 400715, China;
2. Department of Applied Mathematics, The Hong Kong Polytechnic University, Hung Hom, Hong Kong, China;
3. College of Mathematics and Statistics, Chongqing University, Chongqing 401331, China;
4. School of Sciences, Southwest Petroleum University, Chengdu 610500, China;
5. College of Mathematics and Statistics, Chongqing University, Chongqing 401331, China

收稿日期:2023-01-21 修回日期:2023-06-02 出版日期:2024-06-25 发布日期:2024-05-21

DYNAMICS FOR A CHEMOTAXIS MODEL WITH GENERAL LOGISTIC DAMPING AND SIGNAL DEPENDENT MOTILITY

Xinyu Tu^1,2, Chunlai Mu^3,*, Shuyan Qiu⁴, Jing Zhang⁵

1. School of Mathematics and Statistics, Southwest University, Chongqing 400715, China;
2. Department of Applied Mathematics, The Hong Kong Polytechnic University, Hung Hom, Hong Kong, China;
3. College of Mathematics and Statistics, Chongqing University, Chongqing 401331, China;
4. School of Sciences, Southwest Petroleum University, Chengdu 610500, China;
5. College of Mathematics and Statistics, Chongqing University, Chongqing 401331, China

Received:2023-01-21 Revised:2023-06-02 Online:2024-06-25 Published:2024-05-21
Contact: *Chunlai Mu, E-mail:clmu2005@163.com
About author:Xinyu Tu,E-mail:xinyutututu@163.com;Shuyan Qiu, E-mail:shuyanqiu0701@126.com; Jing Zhang, E-mail:zj188838@163.com
Supported by:
Tu's work was supported by the NSFC (12301260), the Hong Kong Scholars Program (XJ2023002, 2023-078), the Double First-Class Construction-Talent Introduction of Southwest University (SWU-KR22037) and the Chongqing Post-Doctoral Fund for Staying in Chongqing (2022); Mu's work was partially supported by the NSFC (12271064, 11971082), the Chongqing Talent Support Program (cstc2022ycjh-bgzxm0169), the Natural Science Foundation of Chongqing (cstc2021jcyj-msxmX1051), the Fundamental Research Funds for the Central Universities (2020CDJQY-Z001, 2019CDJCYJ001) and the Key Laboratory of Nonlinear Analysis and its Applications (Chongqing University), Ministry of Education, and Chongqing Key Laboratory of Analytic Mathematics and Applications; Qiu's work was supported by the NSFC (12301261), the Scientific Research Starting Project of SWPU (2021QHZ016), the Sichuan Science and Technology Program (2023NSFSC1365) and the Nanchong Municipal Government-Universities Scientific Cooperation Project(SXHZ045); Zhang's work was supported by the China Scholarship Council (202206050060) and the Graduate Research and Innovation Foundation of Chongqing (CYB22044).

摘要/Abstract

摘要： In this paper, we consider the fully parabolic chemotaxis system with the general logistic source
$\begin{eqnarray*}\left\{\begin{array}{llll}u_t= \Delta(\gamma(v) u )+\lambda u-\mu u^{\kappa},~~~ &x \in \Omega, ~t>0,\\ v_t= \Delta v+wz, &x \in \Omega, ~t>0,\\w_t= -wz, &x \in \Omega, ~t>0,\\z_t= \Delta z - z+ u, &x\in \Omega, ~t>0,\\\end{array}\right.\end{eqnarray*}$
where $\Omega\subset \mathbb{R}^n (n\geq 1)$ is a smooth and bounded domain, $\lambda\geq 0, \mu\geq 0, \kappa>1$, and the motility function satisfies that $\gamma(v)\in C^3([0, \infty))$, $\gamma(v)>0$, $\gamma{'}(v)\leq0$ for all $v\geq 0$. Considering the Neumann boundary condition, we obtain the global boundedness of solutions if one of the following conditions holds: (i) $ \lambda=\mu=0, 1\leq n\leq 3; $(ii) $ \lambda> 0, \mu>0, ~\text{combined with}~ \kappa>1, 1\leq n\leq 3 ~~\text{or}~~\kappa>\frac{n+2}{4}, n>3. $ Moreover,we prove that the solution $(u, v, w, z)$ exponentially converges to the constant steady state $\left(\left(\frac{\lambda}{\mu}\right)^{\frac{1}{\kappa-1}}, \frac{\int_{\Omega}v_0{\rm d}x+\int_{\Omega}w_0{\rm d}x}{|\Omega|}, 0, \left(\frac{\lambda}{\mu}\right)^{\frac{1}{\kappa-1}}\right)$.

关键词: chemotaxis, signal-dependent motility, logistic source, boundedness, asymptotic behavior

Abstract: In this paper, we consider the fully parabolic chemotaxis system with the general logistic source
$\begin{eqnarray*}\left\{\begin{array}{llll}u_t= \Delta(\gamma(v) u )+\lambda u-\mu u^{\kappa},~~~ &x \in \Omega, ~t>0,\\ v_t= \Delta v+wz, &x \in \Omega, ~t>0,\\w_t= -wz, &x \in \Omega, ~t>0,\\z_t= \Delta z - z+ u, &x\in \Omega, ~t>0,\\\end{array}\right.\end{eqnarray*}$
where $\Omega\subset \mathbb{R}^n (n\geq 1)$ is a smooth and bounded domain, $\lambda\geq 0, \mu\geq 0, \kappa>1$, and the motility function satisfies that $\gamma(v)\in C^3([0, \infty))$, $\gamma(v)>0$, $\gamma{'}(v)\leq0$ for all $v\geq 0$. Considering the Neumann boundary condition, we obtain the global boundedness of solutions if one of the following conditions holds: (i) $ \lambda=\mu=0, 1\leq n\leq 3; $(ii) $ \lambda> 0, \mu>0, ~\text{combined with}~ \kappa>1, 1\leq n\leq 3 ~~\text{or}~~\kappa>\frac{n+2}{4}, n>3. $ Moreover,we prove that the solution $(u, v, w, z)$ exponentially converges to the constant steady state $\left(\left(\frac{\lambda}{\mu}\right)^{\frac{1}{\kappa-1}}, \frac{\int_{\Omega}v_0{\rm d}x+\int_{\Omega}w_0{\rm d}x}{|\Omega|}, 0, \left(\frac{\lambda}{\mu}\right)^{\frac{1}{\kappa-1}}\right)$.

Key words: chemotaxis, signal-dependent motility, logistic source, boundedness, asymptotic behavior

中图分类号:

92C17

Xinyu Tu, Chunlai Mu, Shuyan Qiu, Jing Zhang. DYNAMICS FOR A CHEMOTAXIS MODEL WITH GENERAL LOGISTIC DAMPING AND SIGNAL DEPENDENT MOTILITY[J]. 数学物理学报(英文版), 2024, 44(3): 1046-1063.

Xinyu Tu, Chunlai Mu, Shuyan Qiu, Jing Zhang. DYNAMICS FOR A CHEMOTAXIS MODEL WITH GENERAL LOGISTIC DAMPING AND SIGNAL DEPENDENT MOTILITY[J]. Acta mathematica scientia,Series B, 2024, 44(3): 1046-1063.

参考文献

[1] Arumugam G, Tyagi J.Keller-Segel chemotaxis models: A review. Acta Appl Math, 2021, 171: Art 6
[2] Bellomo N, Bellouquid A, Tao Y, Winkler M. Toward a mathematical theory of Keller-Segel models of pattern formation on biological tissues. Math Models Methods Appl Sci, 2015, 25: 1663-1763
[3] Burger M, Laurencot P, Trescases A. Delayed blow-up for chemotaxis models with local sensing. J Lond Math Soc, 2021, 103: 1596-1617
[4] Chu J, Jin H, Xiong L. Global dynamics of a tumor invasion model with/without logistic source. Z Angew Math Phys, 2021, 72: Art 181
[5] Fujie K. Global asymptotic stability in a chemotaxis-growth model for tumor invasion. Discrete Contin Dyn Syst Ser S, 2020, 13: 203-209
[6] Fujie K, Ishida S, Ito A, Yokota T. Large time behavior in a chemotaxis model with nonlinear general diffusion for tumor invasion. Funkcial Ekvac, 2018, 61: 37-80
[7] Fujie K, Ito A, Winkler M, Yokota T. Stabilization in a chemotaxis model for tumor invasion. Discrete Contin Dyn Syst, 2016, 36: 151-169
[8] Fujie K, Ito A, Yokota T. Existence and uniqueness of local classical solutions to modified tumor invasion models of Chaplain-Anderson type. Adv Math Sci Appl, 2014, 24: 67-84
[9] Fujie K, Jiang J. Global existence for a kinetic model of pattern formation with density-suppressed motilities. J Differential Equations, 2020, 269: 5338-5378
[10] Fujie K, Jiang J. Boundedness of classical solutions to a degenerate Keller-Segel type model with signal-dependent motilities. Acta Appl Math, 2021, 176: Art 3
[11] Fujie K, Jiang J. Comparison methods for a Keller-Segel-type model of pattern formations with density-suppressed motilities. Calc Var Partial Differential Equations, 2021, 60: Art 92
[12] From1970 until present: the Keller-Segel model in chemotaxis and its consequences I. Jahresber Deutsch Math-Verein, 2003, 105: 103-165
[13] Ito A. A mass-conserved tumor invasion systemwith quasi-variational degenerate diffusion. Anal Appl, 2022, 20: 615-680
[14] Jin H, Kim Y, Wang Z. Boundedness, stabilization,pattern formation driven by density-suppressed motility. SIAM J Math, 2018, 78: 1632-1657
[15] Jin H, Liu Z, Shi S. Global dynamics of a quasilinear chemotaxis model arising from tumor invasion. Nonlinear Anal: Real World Appl, 2018, 44: 18-39
[16] Jin H, Wang Z. Critical mass on the Keller-Segel system with signal-dependent motility. Proc Amer Math Soc, 2020, 148: 4855-4873
[17] Jin H, Wang Z. The Keller-Segel system with logistic growth and signal-dependent motility. Discrete Contin Dyn Syst Ser B, 2021, 26: 3023-3041
[18] Jin H, Xiang T. Boundedness and exponential convergence in a chemotaxis model for tumor invasion. Nonlinearity, 2016, 29: 3579-3596
[19] Keller E, Segel L. Model for chemotaxis. J Theor Biol, 1971, 30: 225-234
[20] Li D, Wu C. Effects of density-suppressed motility in a two-dimensional chemotaxis model arising from tumor invasion. Z Angew Math Phys, 2020, 71: Art 153
[21] Liu C, Fu X, Liu L, et al. Sequential establishment of stripe patterns in an expanding cell population. Science, 2011, 334: 238-241
[22] Liu Z, Xu J. Large time behavior of solutions for density-suppressed motility system in higher dimensions. J Math Anal Appl, 2019, 475: 1596-1613
[23] Lv W, Wang Q. Global existence for a class of Keller-Segel models with signal-dependent motility and general logistic term. Evol Equ Control Theory, 2021, 10: 25-36
[24] Lv W, Wang Q. An $n$-dimensional chemotaxis system with signal-dependent motility and generalized logistic source: global existence and asymptotic stabilization. Proc Roy Soc Edinburgh Sect A, 2021, 151: 821-841
[25] Lyu W, Wang Z. Logistic damping effect in chemotaxis models with density-suppressed motility. Adv Nonlinear Anal, 2022, 12: 336-355
[26] Mizoguchi N, Souplet P. Nondegeneracy of blow-up points for the parabolic Keller-Segel system. Ann Inst H Poincaré Anal Non Liné$aire, 2014, 31: 851-875
[27] Osawa R, Yokota T. Boundedness in a chemotaxis model with nonlinear diffusion and logistic type source for tumor invasion. Adv Math Sci Appl, 2018, 27: 225-240
[28] Tao X, Fang Z. Global boundedness and stability in a density-suppressed motility model with generalized logistic source and nonlinear signal production. Z Angew Math Phys, 2022, 73: Art 123
[29] Tao Y, Winkler M. Effects of signal-dependent motilities in a Keller-Segel-type reaction-diffusion system. Math Models Methods Appl Sci, 2017, 27: 1645-1683
[30] Teller J. On a comparison method for a parabolic-elliptic system of chemotaxis with density-suppressed motility and logistic growth. Rev Real Acad Cienc Exactas Fis Nat Ser A-Mat, 2022, 116: Art 109
[31] Tu X, Mu C, Qiu S, Zhang J. Boundedness and asymptotic stability in a chemotaxis model with signal-dependent motility and nonlinear signal secretion. Commun Math Anal Appl, 2022, 1: 568-589
[32] Wang J, Wang M. Boundedness in the higher-dimensional Keller-Segel model with signal-dependent motility and logistic growth. J Math Phys, 2019, 60: 011507
[33] Winkler M. Aggregation vs. global diffusive behavior in the higher-dimensional Keller-Segel model. J Differential Equation, 2010, 248: 2889-2905
[34] Yoon C, Kim Y. Global existence and aggregation in a Keller-Segel model with Fokker-Planck diffusion. Acta Appl Math, 2017, 149: 101-123

DYNAMICS FOR A CHEMOTAXIS MODEL WITH GENERAL LOGISTIC DAMPING AND SIGNAL DEPENDENT MOTILITY

DYNAMICS FOR A CHEMOTAXIS MODEL WITH GENERAL LOGISTIC DAMPING AND SIGNAL DEPENDENT MOTILITY

摘要/Abstract

引用本文

使用本文

参考文献

相关文章 15

Metrics

本文评价

推荐阅读 10

[1]	Xiaoshan Wang, Zhongqian Wang, Zhe Jia. GLOBAL WEAK SOLUTIONS FOR AN ATTRACTION-REPULSION CHEMOTAXIS SYSTEM WITH $p$-LAPLACIAN DIFFUSION AND LOGISTIC SOURCE[J]. 数学物理学报(英文版), 2024, 44(3): 909-924.
[2]	Xianyong Huang, Xunhuan Deng, Qiru Wang. THE ASYMPTOTIC BEHAVIOR AND OSCILLATION FOR A CLASS OF THIRD-ORDER NONLINEAR DELAY DYNAMIC EQUATIONS[J]. 数学物理学报(英文版), 2024, 44(3): 925-946.
[3]	Wei Ding, Yan Tang, Yueping Zhu. THE BOUNDEDNESS OF OPERATORS ON WEIGHTED MULTI-PARAMETER LOCAL HARDY SPACES^*[J]. 数学物理学报(英文版), 2024, 44(1): 386-404.
[4]	Yuecai Han, Dingwen Zhang. NADARAYA-WATSON ESTIMATORS FOR REFLECTED STOCHASTIC PROCESSES^*[J]. 数学物理学报(英文版), 2024, 44(1): 143-160.
[5]	Fen HE, Zhen WANG, Tingting CHEN. THE SHOCK WAVES FOR A MIXED-TYPE SYSTEM FROM CHEMOTAXIS^∗[J]. 数学物理学报(英文版), 2023, 43(4): 1717-1734.
[6]	Minghua Yang, Jinyi Sun, Zunwei Fu, Zheng Wang. THE SINGULAR CONVERGENCE OF A CHEMOTAXIS-FLUID SYSTEM MODELING CORAL FERTILIZATION^*[J]. 数学物理学报(英文版), 2023, 43(2): 492-504.
[7]	Haiyang Jin, Kaiying Xu. BOUNDEDNESS OF A CHEMOTAXIS-CONVECTION MODEL DESCRIBING TUMOR-INDUCED ANGIOGENESIS^*[J]. 数学物理学报(英文版), 2023, 43(1): 156-168.
[8]	Yujuan CHEN, Lei WEI, Yimin ZHANG. THE ASYMPTOTIC BEHAVIOR AND SYMMETRY OF POSITIVE SOLUTIONS TO p-LAPLACIAN EQUATIONS IN A HALF-SPACE[J]. 数学物理学报(英文版), 2022, 42(5): 2149-2164.
[9]	江杰. BOUNDEDNESS AND EXPONENTIAL STABILIZATION IN A PARABOLIC-ELLIPTIC KELLER–SEGEL MODEL WITH SIGNAL-DEPENDENT MOTILITIES FOR LOCAL SENSING CHEMOTAXIS[J]. 数学物理学报(英文版), 2022, 42(3): 825-846.
[10]	邱蜀燕, 穆春来, 易红. BOUNDEDNESS AND ASYMPTOTIC STABILITY IN A PREDATOR-PREY CHEMOTAXIS SYSTEM WITH INDIRECT PURSUIT-EVASION DYNAMICS[J]. 数学物理学报(英文版), 2022, 42(3): 1035-1057.
[11]	麻雅娴, 张显文. ASYMPTOTIC GROWTH BOUNDS FOR THE VLASOV-POISSON SYSTEM WITH RADIATION DAMPING[J]. 数学物理学报(英文版), 2022, 42(1): 91-104.
[12]	金建军, 唐树安. GENERALIZED CESÀRO OPERATORS ON DIRICHLET-TYPE SPACES[J]. 数学物理学报(英文版), 2022, 42(1): 212-220.
[13]	宋乃琪, 刘和平, 赵纪满. BILINEAR SPECTRAL MULTIPLIERS ON HEISENBERG GROUPS[J]. 数学物理学报(英文版), 2021, 41(3): 968-990.
[14]	Abdelkrim MOUSSAOUI, Jean VELIN. EXISTENCE AND BOUNDEDNESS OF SOLUTIONS FOR SYSTEMS OF QUASILINEAR ELLIPTIC EQUATIONS[J]. 数学物理学报(英文版), 2021, 41(2): 397-412.
[15]	樊继山, 栗付才, Gen NAKAMURA. THE LOCAL WELL-POSEDNESS OF A CHEMOTAXIS-SHALLOW WATER SYSTEM WITH VACUUM[J]. 数学物理学报(英文版), 2021, 41(1): 231-240.