Contribution of biodiversity to ecosystem functioning:a non-equilibrium thermodynamic perspective 被引量：1

Contribution of biodiversity to ecosystem functioning:a non-equilibrium thermodynamic perspective

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摘要 Ecosystem stays far from thermodynamic equilibrium. Through the interactions among biotic and abiotic components, and encompassing physical environments, ecosystem forms a dissipative struc- ture that allows it to dissipate energy continuously and thereby remains functional over time. Biotic regulation of energy and material fluxes in and out of the ecosystem allows it to maintain a homeostatic state which corresponds to a self-organized state emerged in a non-equilibrium thermodynamic system. While the associated self-organizational processes approach to homeostatic state, entropy （a measure of irre- versibility） degrades and dissipation of energy increases. We propose here that at a homeostatic state of ecosystem, biodiversity which includes both phenotypic and functional diversity, attains optimal values. As long as biodiversity remains within its optimal range, the corresponding homeostatic state is maintained. However, while embedded environmental conditions fluctuate along the gradient of accelerating changes, phenotypic diversity and functional diversity contribute inversely to the associated self-organizing proc- esses. Furthermore, an increase or decrease in biodiversity outside of its optimal range makes the eco- system vulnerable to transition into a different state. Ecosystem stays far from thermodynamic equilibrium. Through the interactions among biotic and abiotic components, and encompassing physical environments, ecosystem forms a dissipative struc- ture that allows it to dissipate energy continuously and thereby remains functional over time. Biotic regulation of energy and material fluxes in and out of the ecosystem allows it to maintain a homeostatic state which corresponds to a self-organized state emerged in a non-equilibrium thermodynamic system. While the associated self-organizational processes approach to homeostatic state, entropy （a measure of irre- versibility） degrades and dissipation of energy increases. We propose here that at a homeostatic state of ecosystem, biodiversity which includes both phenotypic and functional diversity, attains optimal values. As long as biodiversity remains within its optimal range, the corresponding homeostatic state is maintained. However, while embedded environmental conditions fluctuate along the gradient of accelerating changes, phenotypic diversity and functional diversity contribute inversely to the associated self-organizing proc- esses. Furthermore, an increase or decrease in biodiversity outside of its optimal range makes the eco- system vulnerable to transition into a different state.

作者 Amit CHAKRABORTY B Larry LI

机构地区 Ecological Complexity and Modeling Laboratory XIEG-UCR International Center for Arid Land Ecology

出处《Journal of Arid Land》 SCIE 2011年第1期71-74,共4页 干旱区科学（英文版）

基金 supported by the U.S. National Science Foundation's Biocomplexity Program (DEB-0421530) Long-Term Ecological Research Program (Sevilleta LTER,DEB-0620482)

关键词 ECOSYSTEM SELF-ORGANIZATION non-equilibrium thermodynamics functional diversity phenotypic diversity ecosystem self-organization non-equilibrium thermodynamics functional diversity phenotypic diversity

分类号 Q16 [生物学—普通生物学] TK123 [动力工程及工程热物理—工程热物理]

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