TY - JOUR
T1 - The multiple-mechanisms hypothesis of biodiversity–stability relationships
AU - Eisenhauer, Nico
AU - Mueller, Kevin
AU - Ebeling, Anne
AU - Gleixner, Gerd
AU - Huang, Yuanyuan
AU - Madaj, Anna Maria
AU - Roscher, Christiane
AU - Weigelt, Alexandra
AU - Bahn, Michael
AU - Bonkowski, Michael
AU - Brose, Ulrich
AU - Cesarz, Simone
AU - Feilhauer, Hannes
AU - Guimaraes-Steinicke, Claudia
AU - Heintz-Buschart, Anna
AU - Hines, Jes
AU - Lange, Markus
AU - Meyer, Sebastian T.
AU - Mohanbabu, Neha
AU - Mommer, Liesje
AU - Neuhauser, Sigrid
AU - Oelmann, Yvonne
AU - Rahmanian, Soroor
AU - Sasaki, Takehiro
AU - Scheu, Stefan
AU - Schielzeth, Holger
AU - Schmid, Bernhard
AU - Schloter, Michael
AU - Schulz, Stefanie
AU - Unsicker, Sybille B.
AU - Vogel, Cordula
AU - Weisser, Wolfgang W.
AU - Isbell, Forest
PY - 2024/9
Y1 - 2024/9
N2 - Long-term research in grassland biodiversity experiments has provided empirical evidence that ecological and evolutionary processes are intertwined in determining both biodiversity–ecosystem functioning (BEF) and biodiversity–stability relationships. Focusing on plant diversity, we hypothesize that multifunctional stability is highest in high-diversity plant communities and that biodiversity–stability relationships increase over time due to a variety of forms of ecological complementarity including the interaction with other biota above and below ground. We introduce the multiple-mechanisms hypothesis of biodiversity–stability relationships suggesting that it is not an individual mechanism that drives long-term biodiversity effects on ecosystem functioning and stability but that several intertwined processes produce increasingly positive ecosystem effects. The following six mechanisms are important. Low-diversity plant communities accumulate more plant antagonists over time (1), and use resources less efficiently and have more open, leaky nutrient cycles (2). Conversely, high-diversity plant communities support a greater diversity and activity of beneficial interaction partners across trophic levels (3); diversify in their traits over time and space, within and across species, to optimize temporal (intra- and interannual) and spatial complementarity (4), create a more stable microclimate (5), and foster higher top-down control of aboveground and belowground herbivores by predators (6). In line with the observation that different species play unique roles in ecosystems that are dynamic and multifaceted, the particular mechanism contributing most to the higher performance and stability of diverse plant communities might differ across ecosystem functions, years, locations, and environmental change scenarios. This indicates “between-context insurance” or “across-context complementarity” of different mechanisms. We introduce examples of experiments that will be conducted to test our hypotheses and which might inspire additional work.
AB - Long-term research in grassland biodiversity experiments has provided empirical evidence that ecological and evolutionary processes are intertwined in determining both biodiversity–ecosystem functioning (BEF) and biodiversity–stability relationships. Focusing on plant diversity, we hypothesize that multifunctional stability is highest in high-diversity plant communities and that biodiversity–stability relationships increase over time due to a variety of forms of ecological complementarity including the interaction with other biota above and below ground. We introduce the multiple-mechanisms hypothesis of biodiversity–stability relationships suggesting that it is not an individual mechanism that drives long-term biodiversity effects on ecosystem functioning and stability but that several intertwined processes produce increasingly positive ecosystem effects. The following six mechanisms are important. Low-diversity plant communities accumulate more plant antagonists over time (1), and use resources less efficiently and have more open, leaky nutrient cycles (2). Conversely, high-diversity plant communities support a greater diversity and activity of beneficial interaction partners across trophic levels (3); diversify in their traits over time and space, within and across species, to optimize temporal (intra- and interannual) and spatial complementarity (4), create a more stable microclimate (5), and foster higher top-down control of aboveground and belowground herbivores by predators (6). In line with the observation that different species play unique roles in ecosystems that are dynamic and multifaceted, the particular mechanism contributing most to the higher performance and stability of diverse plant communities might differ across ecosystem functions, years, locations, and environmental change scenarios. This indicates “between-context insurance” or “across-context complementarity” of different mechanisms. We introduce examples of experiments that will be conducted to test our hypotheses and which might inspire additional work.
KW - Biodiversity change
KW - Biodiversity–ecosystem functioning
KW - Complementarity
KW - Recovery
KW - Resilience
KW - Resistance
U2 - 10.1016/j.baae.2024.07.004
DO - 10.1016/j.baae.2024.07.004
M3 - Article
AN - SCOPUS:85200768129
SN - 1439-1791
VL - 79
SP - 153
EP - 166
JO - Basic and Applied Ecology
JF - Basic and Applied Ecology
ER -