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Biodiversity increases the efficiency of energy use in grasslands


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Eat or be eaten

Biodiversity increases the efficiency of energy use in grasslands

Plants obtain their energy from the sun. Other beings rely on eating to survive. Yet how does the energy flow inside ecosystems function and are there differences between ecosystems with many species in comparison to those with few species? Researchers have now examined these questions using a holistic approach by evaluating data gathered through a large-scale biodiversity experiment.

For the first time, they did not just investigate one feeding type such as herbivores but the integrated feeding relationships across an entire ecosystem. Previous research examining the effects of biodiversity on the functioning of ecosystems focused mainly on single feeding levels (trophic levels) or simplified food chains.

"We have analyzed an entire feeding network - in other words, multitrophic interactions - above and belowground. This is indispensable for understanding the effects resulting from global species extinction," explained Dr. Sebastian T. Meyer, a researcher at the Chair for Terrestrial Ecology at the Technical University of Munich (TUM) and lead author of the study.

A network of energy

An aboveground food chain could extend from grasses to grasshoppers and on to spiders, for example. The research group examined how much energy flows into the system, how much remains in the system - so how much biomass is present in the system - and eventually, how much energy is leaving the system. The main insight: The entire ecosystem's efficiency rises across all feeding levels when plant diversity increases.

"Seeing positive effects on one level does not imply that there cannot be simultaneous positive effects on other feeding levels". When a grasshopper feeds on grasses until it is saturated, this does not necessarily result in negative effects on the plant level - with a high level of biodiversity, the system keeps itself in a balance.

Unique database from a grassland biodiversity experiment

The group worked with data gathered through the Jena Experiment, a large-scale grassland biodiversity experiment that has been running since 2002. The research environment provided by the experiment is unique in the world and allow for the synthesis of large amounts of data.

For each of the 80 plots of the Jena Experiment, the researchers assembled trophic network models of the grassland ecosystem. These contain the standing biomass on every feeding level and the flow of energy through feeding interactions between the trophic levels. In addition to plants, the study also covers herbivores, carnivores, omnivores, soil microbes, dead organic material aboveground and in the soil and decomposers that feed on these sources of organic matter.

More efficient energy use in ecosystems with higher plant diversity

"The study shows that higher plant diversity leads to more energy stored, greater energy flow and higher energy-use efficiency in the entire trophic network, therefore across all trophic levels", explained Dr. Oksana Buzhdygan from Freie Universität Berlin, another lead author of the study.

Ecosystems with 60 plant species contained, on average, twice the amount of standing biomass in comparison to plant monocultures, which means that the total amount of resources used and recovered by plant and animal community rose with an increase in plant diversity.

Biodiversity as insurance against environmental fluctuations

"An enhanced ecosystem functionality on all levels can contribute to an increased insurance effect of biodiversity on ecosystem functions when environmental fluctuations occur; it also enhances the system's robustness in case of perturbations", Prof. Jana Petermann from the University of Salzburg concluded. She is the senior author of the study.

This research paper highlights the importance of biodiversity for functions in and services provided by ecosystems. For instance, agricultural land use that aims at yielding a wide range of goods and services should maintain high plant diversity, for example by planting mixed crops, in order to avoid losing ecosystem resources.


Oksana Y. Buzhdygan, Sebastian T. Meyer, Wolfgang W. Weisser, Nico Eisenhauer, Anne Ebeling, Stuart R. Borrett, Nina Buchmann, Roeland Cortois, Gerlinde B. De Deyn, Hans de Kroon, Gerd Gleixner, Lionel R. Hertzog, Jes Hines, Markus Lange, Liesje Mommer, Janneke Ravenek, Christoph Scherber, Michael Scherer-Lorenzen, Stefan Scheu, Bernhard Schmid, Katja Steinauer, Tanja Strecker, Britta Tietjen, Anja Vogel, Alexandra Weigelt, Jana S. Petermann (2020). Biodiversity increases multitrophic energy use efficiency, flow and storage in grasslands. Nature Ecology & Evolution. DOI: 10.1038/s41559-020-1123-8.


Further information:

In the so-called "Jena Experiment" (, scientists from various universities in Germany, the Netherlands and Switzerland study the significance of biological diversity (biodiversity) for ecosystems. Grasslands of varying diversity are used as a model system. In the year 2002, plant communities of 1-60 plant species and 1-4 plant functional groups (based on a species pool of 60 species) were sown to measure and compare flows in biogeochemical cycles and the interactions between organisms. The results show that a higher plant diversity leads to multifaceted positive effects for these cycles and other processes in the ecosystem. Many of the results from the examined model systems can be applied to other ecosystems as well as agricultural areas.

The Chair of Professor Wolfgang Weisser is part of the Hans-Eisenmann-Forum (HEF) for Agricultural Sciences, a Central Institute of TUM.

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Prof. Dr. Wolfgang Weisser

Technical University of Munich

Chair for Terrestrial Ecology

Tel.: +49.8161.71.3496

Dr. Sebastian T. Meyer

Tel.: +49.8161.71.4219

The Technical University of Munich (TUM) is one of Europe's leading research universities, with around 550 professors, 43,000 students, and 10,000 academic and non-academic staff. Its focus areas are the engineering sciences, natural sciences, life sciences and medicine, combined with economic and social sciences. TUM acts as an entrepreneurial university that promotes talents and creates value for society. In that it profits from having strong partners in science and industry. It is represented worldwide with the TUM Asia campus in Singapore as well as offices in Beijing, Brussels, Cairo, Mumbai, San Francisco, and São Paulo. Nobel Prize winners and inventors such as Rudolf Diesel, Carl von Linde, and Rudolf Mößbauer have done research at TUM. In 2006, 2012, and 2019 it won recognition as a German "Excellence University." In international rankings, TUM regularly places among the best universities in Germany.

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