Self-organization, Scale and Stability in a Spatial Predator–Prey Interaction

Simple predator–prey models often predict extreme instability in interactions where the prey are depressed well below their carrying capacity. Although the behaviour of some laboratory systems conforms to this pattern, field and mesocosm studies generally show prolonged co-existence of prey and pred...

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Veröffentlicht in:	Bulletin of mathematical biology 2000-01, Vol.62 (1), p.61-86
Hauptverfasser:	Gurney, William S.C., Veitch, A.Roy
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Sprache:	eng
Schlagworte:	Animals Computer Simulation Models, Biological Predatory Behavior
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creator	Gurney, William S.C. Veitch, A.Roy
description	Simple predator–prey models often predict extreme instability in interactions where the prey are depressed well below their carrying capacity. Although the behaviour of some laboratory systems conforms to this pattern, field and mesocosm studies generally show prolonged co-existence of prey and predator. Prominent among the possible causes of this discrepancy are the effects of spatial heterogeneity. In this paper we show that both discrete and continuous representations of the spatial Rosenzweig–McArthur model with immobile prey can be stabilized by self-organized prey heterogeneity. This concordance of behaviour closely parallels that which we have previously established in the context of invasion waves. We use the continuous model variant to calculate the characteristic spatial scales of the self-organized structures. The discrete variant forms the basis of a simulation study demonstrating the variety of stable structures and elucidating their relation to the history of the system. We note that all stable prey distributions take the form of a network of occupied patches separated by prey-free regions, and liken the process which generates such assemblages to the formation of a landscape mozaic.
doi_str_mv	10.1006/bulm.1999.0130
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subjects	Animals Computer Simulation Models, Biological Predatory Behavior
title	Self-organization, Scale and Stability in a Spatial Predator–Prey Interaction
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