TY - JOUR
T1 - Consistent Effects of Biodiversity on Ecosystem Functioning Under Varying Density and Evenness
AU - Schmitz, Martin
AU - Flynn, Dan F.B.
AU - Mwangi, Peter N.
AU - Schmid, Roland
AU - Scherer-Lorenzen, Michael
AU - Weisser, Wolfgang W.
AU - Schmid, Bernhard
N1 - Funding Information:
Acknowledgements As part of the Jena Experiment this study was funded by the Deutsche Forschungsgemeinschaft (DFG-grant FOR 456), and supported by the Friedrich Schiller University of Jena, the Max Planck Society and the Institute of Evolutionary Biology and Environmental Studies at the University of Zürich (BS). We are grateful to the many people who helped with set-up and maintenance of the plots, particularly the gardeners S. Eismann, S. Junghans, B. Lenk, H. Scheffler and U. Wehmeier. We also thank the many student helpers who worked during the weeding campaigns, assisted the biomass harvest and data collection, especially the TP 10 team: M. Rzanny, A. Gminder, A. Fröhlich, J. Trettin, A. Dassler, J. Dittmann, M. Geuther, L. Merbold and V. Höntsch. An earlier version of this manuscript benefited greatly from suggestions by R. F. Doren.
PY - 2013/9
Y1 - 2013/9
N2 - Biodiversity experiments typically vary only species richness and composition, yet the generality of their results relies on consistent effects of these factors even under varying starting conditions of density and evenness. We tested this assumption in a factorial species richness x density x evenness experiment using a pool of 60 common grassland species divided into four functional groups (grasses, legumes, tall herbs and short herbs). Richness varied from 1, 2, 4, 8 to 16 species, total planting density was 1,000 or 2,000 seeds/m2, and species were sown in even or uneven proportions, where one functional group was made dominant. Aboveground plant biomass increased linearly with the logarithm of species richness in all density and evenness treatments during all three years of the experiment. This was due to a convergence of realized density and evenness within species richness levels, although functional groups which were initially made dominant retained their dominance. Between species richness levels, realized density increased, and realized evenness decreased with species richness. Thus, more individuals could coexist if they belonged to different species. Within species richness levels, higher biomass values were correlated with lower density, suggesting an underlying thinning process. However, communities with low realized evenness also had low biomass values; thus high biomass did not result from species dominance. So-called complementarity and selection effects were similar across density and evenness treatments, indicating that the mechanisms underpinning the biodiversity effects were not altered. Species richness was the dominant driver of aboveground biomass, irrespective of variations in total densities and species abundance distributions at the start of the experiment; rejecting the hypothesis that initial differences in species abundance distributions might lead to different "stable states" in community structure or biomass. Thus, results from previous biodiversity experiments that only manipulated species richness and composition should be quite robust and broadly generalizable.
AB - Biodiversity experiments typically vary only species richness and composition, yet the generality of their results relies on consistent effects of these factors even under varying starting conditions of density and evenness. We tested this assumption in a factorial species richness x density x evenness experiment using a pool of 60 common grassland species divided into four functional groups (grasses, legumes, tall herbs and short herbs). Richness varied from 1, 2, 4, 8 to 16 species, total planting density was 1,000 or 2,000 seeds/m2, and species were sown in even or uneven proportions, where one functional group was made dominant. Aboveground plant biomass increased linearly with the logarithm of species richness in all density and evenness treatments during all three years of the experiment. This was due to a convergence of realized density and evenness within species richness levels, although functional groups which were initially made dominant retained their dominance. Between species richness levels, realized density increased, and realized evenness decreased with species richness. Thus, more individuals could coexist if they belonged to different species. Within species richness levels, higher biomass values were correlated with lower density, suggesting an underlying thinning process. However, communities with low realized evenness also had low biomass values; thus high biomass did not result from species dominance. So-called complementarity and selection effects were similar across density and evenness treatments, indicating that the mechanisms underpinning the biodiversity effects were not altered. Species richness was the dominant driver of aboveground biomass, irrespective of variations in total densities and species abundance distributions at the start of the experiment; rejecting the hypothesis that initial differences in species abundance distributions might lead to different "stable states" in community structure or biomass. Thus, results from previous biodiversity experiments that only manipulated species richness and composition should be quite robust and broadly generalizable.
KW - Biodiversity-productivity relationship
KW - Multiple stable states
KW - Richness × density × evenness experiment
UR - http://www.scopus.com/inward/record.url?scp=84885924297&partnerID=8YFLogxK
U2 - 10.1007/s12224-013-9177-x
DO - 10.1007/s12224-013-9177-x
M3 - Article
AN - SCOPUS:84885924297
SN - 1211-9520
VL - 48
SP - 335
EP - 353
JO - Folia Geobotanica
JF - Folia Geobotanica
IS - 3
ER -