Phenotypic Diversity and Ecosystem Functioning in Changing Environments: A Theoretical Framework

Biodiversity plays a vital role for ecosystem functioning in a changing environment. Yet theoretical approaches that incorporate diversity into classical ecosystem theory do not provide a general dynamic theory based on mechanistic principles. In this paper, we suggest that approaches developed for...

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Veröffentlicht in:	Proceedings of the National Academy of Sciences - PNAS 2001-09, Vol.98 (20), p.11376-11381
Hauptverfasser:	Norberg, Jon, Swaney, Dennis P., Dushoff, Jonathan, Lin, Juan, Casagrandi, Renato, Levin, Simon A.
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Sprache:	eng
Schlagworte:	Approximation Biodiversity Biological Sciences Biomass Ecology Ecosystem Ecosystem models Ecosystems Environment Functional groups Genetic diversity Mathematical moments Mathematics Models, Biological Phenotype Phenotypes Productivity Species Studies Theory
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container_title	Proceedings of the National Academy of Sciences - PNAS
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creator	Norberg, Jon Swaney, Dennis P. Dushoff, Jonathan Lin, Juan Casagrandi, Renato Levin, Simon A.
description	Biodiversity plays a vital role for ecosystem functioning in a changing environment. Yet theoretical approaches that incorporate diversity into classical ecosystem theory do not provide a general dynamic theory based on mechanistic principles. In this paper, we suggest that approaches developed for quantitative genetics can be extended to ecosystem functioning by modeling the means and variances of phenotypes within a group of species. We present a framework that suggests that phenotypic variance within functional groups is linearly related to their ability to respond to environmental changes. As a result, the long-term productivity for a group of species with high phenotypic variance may be higher than for the best single species, even though high phenotypic variance decreases productivity in the short term, because suboptimal species are present. In addition, we find that in the case of accelerating environmental change, species succession in a changing environment may become discontinuous. Our work suggests that this phenomenon is related to diversity as well as to the environmental disturbance regime, both of which are affected by anthropogenic activities. By introducing new techniques for modeling the aggregate behavior of groups of species, the present approach may provide a new avenue for ecosystem analysis.
doi_str_mv	10.1073/pnas.171315998
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subjects	Approximation Biodiversity Biological Sciences Biomass Ecology Ecosystem Ecosystem models Ecosystems Environment Functional groups Genetic diversity Mathematical moments Mathematics Models, Biological Phenotype Phenotypes Productivity Species Studies Theory
title	Phenotypic Diversity and Ecosystem Functioning in Changing Environments: A Theoretical Framework
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