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Volume 30, Issue 1 e02014
Article

Soil heterogeneity increases plant diversity after 20 years of manipulation during grassland restoration

Sara G. Baer

Corresponding Author

Sara G. Baer

Kansas Biological Survey and Department of Ecology & Evolutionary Biology, University of Kansas, Lawrence, Kansas, 66047 USA

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Tianjiao Adams

Tianjiao Adams

Department of Plant Biology and Center for Ecology, Southern Illinois University, Carbondale, Illinois, 62901 USA

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Drew A. Scott

Drew A. Scott

Department of Plant Biology and Center for Ecology, Southern Illinois University, Carbondale, Illinois, 62901 USA

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John M. Blair

John M. Blair

Division of Biology, Kansas State University, Manhattan, Kansas, 66506 USA

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Scott L. Collins

Scott L. Collins

Department of Biology, University of New Mexico, Albuquerque, New Mexico, 87131 USA

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First published: 06 October 2019
Citations: 31
Corresponding Editor: Elisabeth Huber-Sannwald.

Abstract

The “environmental heterogeneity hypothesis” predicts that variability in resources promotes species coexistence, but few experiments support this hypothesis in plant communities. A previous 15-yr test of this hypothesis in a prairie restoration experiment demonstrated a weak effect of manipulated soil resource heterogeneity on plant diversity. This response was attributed to a transient increase in richness following a post-restoration supplemental propagule addition, occasionally higher diversity under nutrient enrichment, and reduced cover of a dominant species in a subset of soil treatments. Here, we report community dynamics under continuous propagule addition in the same experiment, corresponding to 16–20 yr of restoration, in response to altered availability and heterogeneity of soil resources. We also quantified traits of newly added species to determine if heterogeneity increases the amount and variety of niches available for new species to exploit. The heterogeneous treatment contained a factorial combination of altered nutrient availability and soil depth; control plots had no manipulations. Total diversity and richness were higher in the heterogeneous treatment during this 5-yr study due to higher cover, diversity, and richness of previously established forbs, particularly in the N-enriched subplots. All new species added to the experiment exhibited unique trait spaces, but there was no evidence that heterogeneous plots contained a greater variety of new species representing a wider range of trait spaces relative to the control treatment. The richness and cover of new species was higher in N-enriched soil, but the magnitude of this response was small. Communities assembling under long-term N addition were dominated by different species among subplots receiving added N, leading to greater dispersion of communities among the heterogeneous relative to control plots. Contrary to the deterministic mechanism by which heterogeneity was expected to increase diversity (greater variability in resources for new species to exploit), higher diversity in the heterogeneous plots resulted from destabilization of formerly grass-dominated communities in N-enriched subplots. While we do not advocate increasing available soil N at large scales, we conclude that the positive effect of environmental heterogeneity on diversity can take decades to materialize and depend on development of stochastic processes in communities with strong establishment limitation.