Du, Yihong; Shi, Junping

Author(s)

Du, Yihong

Shi, Junping

Publication Date

2006

Abstract

In this paper we study the effects of a protection zone Ω₀ for the prey on a diffusive predator–prey model with Holling type II response and no-flux boundary condition. We show the existence of a critical patch size described by the principal eigenvalue λ₁D(Ω₀)of the Laplacian operator over Ω₀ with with homogeneous Dirichlet boundary conditions. If the protection zone is over the critical patch size, i.e., if λ₁D(Ω₀) is less than the prey growth rate, then the dynamics of the model is fundamentally changed from the usual predator–prey dynamics; in such a case, the prey population persists regardless of the growth rate of its predator, and if the predator is strong, then the two populations stabilize at a unique coexistence state. If the protection zone is below the critical patch size, then the dynamics of the model is qualitatively similar to the case without protection zone, but the chances of survival of the prey species increase with the size of the protection zone, as generally expected. Our mathematical approach is based on bifurcation theory, topological degree theory, the comparison principles for elliptic and parabolic equations, and various elliptic estimates.

Citation

Journal of Differential Equations, 229(1), p. 63-91

ISSN

1090-2732

0022-0396

Link

https://hdl.handle.net/1959.11/3495

Publisher

Academic Press

Title

A diffusive predator-prey model with a protection zone

Type of document

Journal Article

Entity Type

Publication

Author(s)	Du, Yihong Shi, Junping
Publication Date	2006
Abstract	In this paper we study the effects of a protection zone Ω₀ for the prey on a diffusive predator–prey model with Holling type II response and no-flux boundary condition. We show the existence of a critical patch size described by the principal eigenvalue λ₁D(Ω₀)of the Laplacian operator over Ω₀ with with homogeneous Dirichlet boundary conditions. If the protection zone is over the critical patch size, i.e., if λ₁D(Ω₀) is less than the prey growth rate, then the dynamics of the model is fundamentally changed from the usual predator–prey dynamics; in such a case, the prey population persists regardless of the growth rate of its predator, and if the predator is strong, then the two populations stabilize at a unique coexistence state. If the protection zone is below the critical patch size, then the dynamics of the model is qualitatively similar to the case without protection zone, but the chances of survival of the prey species increase with the size of the protection zone, as generally expected. Our mathematical approach is based on bifurcation theory, topological degree theory, the comparison principles for elliptic and parabolic equations, and various elliptic estimates.
Citation	Journal of Differential Equations, 229(1), p. 63-91
ISSN	1090-2732 0022-0396
Link	https://hdl.handle.net/1959.11/3495
Publisher	Academic Press
Title	A diffusive predator-prey model with a protection zone
Type of document	Journal Article
Entity Type	Publication

A diffusive predator-prey model with a protection zone

Files: