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Partitioning selection and complementarity in biodiversity experiments

An Erratum to this article was published on 04 October 2001


The impact of biodiversity loss on the functioning of ecosystems and their ability to provide ecological services has become a central issue in ecology. Several experiments have provided evidence that reduced species diversity may impair ecosystem processes such as plant biomass production1,2,3,4,5. The interpretation of these experiments, however, has been controversial6,7,8,9,10,11,12 because two types of mechanism may operate in combination6,13,14,15. In the ‘selection effect’, dominance by species with particular traits affects ecosystem processes. In the ‘complementarity effect’, resource partitioning or positive interactions lead to increased total resource use. Here we present a new approach to separate the two effects on the basis of an additive partitioning analogous to the Price equation in evolutionary genetics16,17,18,19. Applying this method to data from the pan-European BIODEPTH experiment4 reveals that the selection effect is zero on average and varies from negative to positive in different localities, depending on whether species with lower- or higher-than-average biomass dominate communities. In contrast, the complementarity effect is positive overall, supporting the hypothesis that plant diversity influences primary production in European grasslands through niche differentiation or facilitation.

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Figure 1: Observed yield YO and net biodiversity effect ΔY as functions of species richness across all localities in mixtures of the BIODEPTH experiment.
Figure 2: Selection effect, N cov(ΔRY, M), as a function of species richness across all localities and at individual localities.
Figure 3: Complementarity effect, N\(\overline{ΔRY}\)\(\overline{M}\), as a function of species richness across all localities and at individual localities.

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We thank S. Yachi, B. Schmid and D. Deutschman for suggestions and all members of BIODEPTH for their input to the project. This work was supported by the CNRS GDR 1936 DIV-ECO and the CNRS PICS Dynamics of biodiversity: from species interactions to ecosystem functioning.

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Correspondence to Michel Loreau.

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Loreau, M., Hector, A. Partitioning selection and complementarity in biodiversity experiments. Nature 412, 72–76 (2001).

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