Merging Spatial and Temporal Structure within a Metapopulation Model

Current research recognizes that both the spatial and temporal structure of the landscape influence species persistence. Patch models that incorporate the spatial structure of the landscape have been used to investigate static habitat destruction by comparing persistence results within nested landsc...

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Veröffentlicht in:	The American naturalist 2005-07, Vol.166 (1), p.42-55
Hauptverfasser:	DeWoody, Yssa D., Feng, Zhilan, Swihart, Robert K.
Format:	Artikel
Sprache:	eng
Schlagworte:	Comparative analysis Connectivity Dynamic modeling Ecosystem Extinction Habitat conservation Habitat destruction Habitats Metapopulation ecology Modeling Models, Biological Patch dynamics Population Dynamics Spatial models Species extinction Time Factors
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container_title	The American naturalist
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creator	DeWoody, Yssa D. Feng, Zhilan Swihart, Robert K.
description	Current research recognizes that both the spatial and temporal structure of the landscape influence species persistence. Patch models that incorporate the spatial structure of the landscape have been used to investigate static habitat destruction by comparing persistence results within nested landscapes. Other researchers have incorporated temporal structure into their models by making habitat suitability a dynamic feature of the landscape. In this article, we present a spatially realistic patch model that allows patches to be in one of three states: uninhabitable, habitable, or occupied. The model is analytically tractable and allows us to explore the interactions between the spatial and temporal structure of the landscape as perceived by the target species. Extinction thresholds are derived that depend on habitat suitability, mean lifetime of a patch, and metapopulation capacity. We find that a species is able to tolerate more ephemeral destruction, provided that the rate of the destruction does not exceed the scale of its own metapopulation dynamics, which is dictated by natural history characteristics and the spatial structure of the landscape. This model allows for an expansion of the classic definition of a patch and should prove useful when considering species inhabiting complex dynamic landscapes, for example, agricultural landscapes.
doi_str_mv	10.1086/430639
format	Article
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source	Jstor Complete Legacy; MEDLINE; EZB-FREE-00999 freely available EZB journals
subjects	Comparative analysis Connectivity Dynamic modeling Ecosystem Extinction Habitat conservation Habitat destruction Habitats Metapopulation ecology Modeling Models, Biological Patch dynamics Population Dynamics Spatial models Species extinction Time Factors
title	Merging Spatial and Temporal Structure within a Metapopulation Model
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