A Residence Time Theory for Biodiversity

From microorganisms to the largest macroorganisms, much of Earth's biodiversity is subject to forces of physical turnover. Residence time is the ratio of an ecosystem's size to its rate of flow and provides a means for understanding the influence of physical turnover on biological systems....

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Published inThe American naturalist Vol. 194; no. 1; p. 59
Main Authors Locey, Kenneth J, Lennon, Jay T
Format Journal Article
LanguageEnglish
Published United States 01.07.2019
Subjects
Biodiversity
Life History Traits
Models, Biological
metabolic theory of ecology
macroecology
individual-based models
emergent properties
dormancy
chemostat
Online AccessGet more information
ISSN1537-5323
DOI10.1086/703456

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Abstract From microorganisms to the largest macroorganisms, much of Earth's biodiversity is subject to forces of physical turnover. Residence time is the ratio of an ecosystem's size to its rate of flow and provides a means for understanding the influence of physical turnover on biological systems. Despite its use across scientific disciplines, residence time has not been integrated into the broader understanding of biodiversity, life history, and the assembly of ecological communities. Here we propose a residence time theory for the growth, activity, abundance, and diversity of traits and taxa in complex ecological systems. Using thousands of stochastic individual-based models to simulate energetically constrained life-history processes, we show that our predictions are conceptually sound and mutually compatible and that they support ecological relationships that underpin much of biodiversity theory. We discuss the importance of residence time across the ecological hierarchy and propose how residence time can be integrated into theories ranging from population genetics to macroecology.
AbstractList From microorganisms to the largest macroorganisms, much of Earth's biodiversity is subject to forces of physical turnover. Residence time is the ratio of an ecosystem's size to its rate of flow and provides a means for understanding the influence of physical turnover on biological systems. Despite its use across scientific disciplines, residence time has not been integrated into the broader understanding of biodiversity, life history, and the assembly of ecological communities. Here we propose a residence time theory for the growth, activity, abundance, and diversity of traits and taxa in complex ecological systems. Using thousands of stochastic individual-based models to simulate energetically constrained life-history processes, we show that our predictions are conceptually sound and mutually compatible and that they support ecological relationships that underpin much of biodiversity theory. We discuss the importance of residence time across the ecological hierarchy and propose how residence time can be integrated into theories ranging from population genetics to macroecology.
Author Lennon, Jay T
Locey, Kenneth J
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crossref_primary_10_1186_s13062_020_00261_8
crossref_primary_10_1128_MMBR_00026_20
crossref_primary_10_1016_j_mib_2023_102348
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Keywords metabolic theory of ecology
macroecology
individual-based models
emergent properties
dormancy
chemostat
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Snippet From microorganisms to the largest macroorganisms, much of Earth's biodiversity is subject to forces of physical turnover. Residence time is the ratio of an...
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StartPage 59
SubjectTerms Biodiversity
Life History Traits
Models, Biological
Title A Residence Time Theory for Biodiversity
URI https://www.ncbi.nlm.nih.gov/pubmed/31251651
Volume 194
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