A spatial model of range-dependent succession
- 1 December 2000
- journal article
- Published by Cambridge University Press (CUP) in Journal of Applied Probability
- Vol. 37 (4) , 1044-1060
- https://doi.org/10.1239/jap/1014843082
Abstract
We consider an interacting particle system in which each site of the d-dimensional integer lattice can be in state 0, 1, or 2. Our aim is to model the spread of disease in plant populations, so think of 0 = vacant, 1 = healthy plant, 2 = infected plant. A vacant site becomes occupied by a plant at a rate which increases linearly with the number of plants within range R, up to some saturation level, F1, above which the rate is constant. Similarly, a plant becomes infected at a rate which increases linearly with the number of infected plants within range M, up to some saturation level, F2. An infected plant dies (and the site becomes vacant) at constant rate δ. We discuss coexistence results in one and two dimensions. These results depend on the relative dispersal ranges for plants and disease.Keywords
This publication has 14 references indexed in Scilit:
- Dependent random graphs and spatial epidemicsThe Annals of Applied Probability, 1998
- Spatial Aspects of Interspecific CompetitionTheoretical Population Biology, 1998
- Coexistence for a catalytic surface reaction modelThe Annals of Applied Probability, 1997
- Spatial epidemics with large finite rangeJournal of Applied Probability, 1996
- A complete convergence theorem for an epidemic modelJournal of Applied Probability, 1996
- Particle Systems and Reaction-Diffusion EquationsThe Annals of Probability, 1994
- Epidemics with Recovery in $D = 2$The Annals of Applied Probability, 1991
- Mathematical BiologyPublished by Springer Nature ,1989
- Limit theorems for the spread of epidemics and forest firesStochastic Processes and their Applications, 1988
- Oriented Percolation in Two DimensionsThe Annals of Probability, 1984