论文信息 - Effects of habitat heterogeneity and dispersal strategies on population persistence in annual plants

Effects of habitat heterogeneity and dispersal strategies on population persistence in annual plants

Abstract Using an integro-difference equation model of population growth and dispersal, the incorporation of habitat heterogeneity is formulated using the ‘habitat quality function’. Using a number of habitat quality functions and dispersal functions, the minimum amount of habitat quality required for population persistence (critical habitat size) is calculated. Results are used to show which types of habitat heterogeneity give populations the best chance of persistence and what effects the choice of dispersal function has.

[1] J. G. Skellam. Random dispersal in theoretical populations , 1951, Biometrika.

[2] M. Andersen. Properties of some density-dependent integrodifference equation population models. , 1991, Mathematical biosciences.

[3] Hans F. Weinberger,et al. Asymptotic behavior of a model in population genetics , 1978 .

[4] R. Veit,et al. Partial Differential Equations in Ecology: Spatial Interactions and Population Dynamics , 1994 .

[5] M. Hassell,et al. Environmental heterogeneity and the stability of host-parasitoid interactions , 1993 .

[6] J. Chadam,et al. Nonlinear Partial Differential Equations and Applications , 1978 .

[7] Douglas P. Hardin,et al. Asymptotic properties of a continuous-space discrete-time population model in a random environment , 1988 .

[8] Mark Kot,et al. Dispersal and Pattern Formation in a Discrete-Time Predator-Prey Model , 1995 .

[9] M. Kot,et al. Discrete-time growth-dispersal models , 1986 .

[10] A. V. Tuzinkevich,et al. Dissipative structures and patchiness in spatial distribution of plants , 1990 .

[11] R. May,et al. Metapopulations and equilibrium stability: the effects of spatial structure. , 1996, Journal of theoretical biology.