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Coexistence Solutions for a Periodic Competition Model with Singular–Degenerate Diffusion

Part of: Partial differential equations Parabolic equations and systems Nonlinear operators and their properties

Published online by Cambridge University Press:  15 December 2016

Yifu Wang ,
Jingxue Yin  and
Yuanyuan Ke
Yifu Wang
Affiliation:
Department of Mathematics, Beijing Institute of Technology, Beijing, 100081, People's Republic of China
Jingxue Yin
Affiliation:
School of Mathematical Sciences, South China Normal University, Guangzhou, 510631, People's Republic of China
Yuanyuan Ke*
Affiliation:
School of Information, Renmin University of China, Beijing, 100872, People's Republic of China ([email protected])
*
*Corresponding author.
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Abstract

We investigate a system of singular–degenerate parabolic equations with non-local terms, which can be regarded as a spatially heterogeneous competition model of Lotka–Volterra type. Applying the Leray–Schauder fixed-point theorem, we establish the existence of coexistence periodic solutions to the problem, which, together with the existing literature, gives a complete picture for such a system for all parameters.

Keywords

coexistence solutionsperiodic competition modelsingular–degenerate diffusion

MSC classification

Secondary: 35K65: Degenerate parabolic equations 35B10: Periodic solutions 47H10: Fixed-point theorems
Type
Research Article
Information
Proceedings of the Edinburgh Mathematical Society , Volume 60 , Issue 4 , November 2017 , pp. 1065 - 1075
Copyright
Copyright © Edinburgh Mathematical Society 2017 

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References

1. Ahmad, S. and Lazer, A., Asymptotic behavior of solutions of periodic competition diffusion systems, Nonlin. Analysis TMA 13 (1989), 263284.Google Scholar
2. Allegretto, W., Fragnelli, G., Nistri, P. and Papini, D., Coexistence and optimal control problems for a degenerate predator–prey model, J. Math. Analysis Applic. 378 (2011), 528540.Google Scholar
3. Cantrell, R. S., Cosner, C. and Lou, Y., Advection-mediated coexistence of competing species, Proc. R. Soc. Edinb. A137 (2007), 497518.Google Scholar
4. Cirmi, G. and Porzio, M., L -solutions for some nonlinear degenerate elliptic and parabolic equations, Annali Mat. Pura Appl. 169 (1995), 6786.Google Scholar
5. Conti, M. and Felli, V., Coexistence and segregation for strongly competing species in special domains, Interfaces Free Bound. 10 (2008), 173195.Google Scholar
6. Delgado, M. and Suárez, A., On the existence of dead cores for degenerate Lotka–Volterra models, Proc. R. Soc. Edinb. A130 (2000), 743766.Google Scholar
7. Du, Y., Positive periodic solutions of a competitor–competitor–mutualist model, Diff. Integ. Eqns 9 (1996), 10431066.Google Scholar
8. Eilbeck, J. C., Furter, J. and López-Gómez, J., Coexistence in the competetion model with diffusion, J. Diff. Eqns 107 (1994), 96139.CrossRefGoogle Scholar
9. Fragnelli, G., Positive periodic solutions for a system of anisotropic parabolic equations, J. Math. Analysis Applic. 367 (2010), 204228.Google Scholar
10. Fragnelli, G., Nistri, P. and Papini, D., Positive periodic solutions and optimal control for a distributed biological model of two interacting species, Nonlin. Analysis RWA 12 (2011), 14101428.Google Scholar
11. Fragnelli, G., Nistri, P. and Papini, D., Non-trivial non-negative periodic solutions of a system of doubly degenerate parabolic equations with nonlocal terms, Discrete Contin. Dynam. Syst. A31 (2011), 3564.Google Scholar
12. Fragnelli, G., Mugnai, D., Nistri, P. and Papini, D., Non-trivial non-negative periodic solutions of a system of singular–degenerate parabolic equations with nonlocal terms, Commun. Contemp. Math. 17(2) (2015), DOI: 10.1142/S0219199714500254.CrossRefGoogle Scholar
13. Hess, P., Periodic-parabolic boundary value problems and positivity, Pitman Research Notes in Mathematics, Volume 247 (Longman, New York, 1991).Google Scholar
14. Ivanov, A. V., Hölder estimates for equations of slow and normal diffusion type, J. Math. Sci. 85 (1997), 16401644.Google Scholar
15. Kawohl, B. and Lindqvist, P., Positive eigenfunctions for the p-Laplace operator revisited, Analysis (Munich) 26 (2006), 545550.Google Scholar
16. Pao, C. V., Periodic solutions of parabolic systems with time delays, J. Math. Analysis Applic. 251 (2000), 251263.Google Scholar
17. Porzio, M. and Vespri, V., Hölder estimates for local solutions of some doubly nonlinear degenerate parabolic equations, J. Diff. Eqns 103 (1993), 146178.Google Scholar
18. Suárez, A., Nonnegative solutions for a heterogeneous degenerate competition model, ANZIAM J. 46 (2004), 273297.Google Scholar
19. Sun, J., Yin, J. and Wang, Y., Asymptotic bounds of solutions for a periodic doubly degenerate parabolic equation, Nonlin. Analysis TMA 74 (2011), 24152424.Google Scholar
20. Tian, C. and Lin, Z., Asymptotic behavior of solutions of a periodic diffusion system of plankton allelopathy, Nonlin. Analysis RWA 11 (2010), 15811588.Google Scholar
21. Tineo, A., Asymptotic behavior of solutions of a periodic reaction–diffusion system of a competitor–competitor–mutualist model, J. Diff. Eqns 108 (1994), 326341.Google Scholar
22. Wang, Y., Yin, J. and Wu, Z., Periodic solutions of porous medium equations with weakly nonlinear sources, Northeastern Math. J. 16 (2000), 475483.Google Scholar
23. Wang, Y., Yin, J. and Ke, Y., Coexistence solutions for a periodic competition model with nonlinear diffusion, Nonlin. Analysis RWA 14 (2013), 10821091.Google Scholar
24. Wu, Z., Yin, J. and Wang, C., Elliptic and parabolic equations (World Scientific, 2006).Google Scholar
25. Yin, J. and Jin, C., Periodic solutions of the evolutionary p-Laplacian with nonlinear sources, J. Math. Analysis Applic. 368 (2010), 604622.Google Scholar
26. Zeidler, E., Nonlinear function analysis and its applications II/B: nonlinear monotone operators (Springer, 1989).Google Scholar
27. Zhou, Q., Ke, Y., Wang, Y. and Yin, J., Periodic p-Laplacian with nonlocal terms, Nonlin. Analysis TMA 66 (2007), 442453.Google Scholar