Methane yield of biomass from extensive grassland is affected by compositional changes induced by order of arrival
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In: Global Change Biology : Bioenergy, Vol. 9, No. 10, 10.2017, p. 1555 - 1562.
Research output: Journal contributions › Journal articles › Research › peer-review
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TY - JOUR
T1 - Methane yield of biomass from extensive grassland is affected by compositional changes induced by order of arrival
AU - Popp, Denny
AU - von Gillhaussen, Philipp
AU - Weidlich, Emanuela W. A.
AU - Sträuber, Heike
AU - Harms, Hauke
AU - Temperton, Victoria Martine
N1 - Funding Information: This work was supported by the portfolio theme Sustainable Bioeconomy of the Helmholtz Association. The Priority Effect Experiment in Ju€lich was set up and funded by IBG-2 (Plant Sciences) in the Forschungszentrum Ju€lich within the working group of Vicky Temperton. We thank the technicians, especially Marlene Mu€ller, Edelgard Scho€lgens, and Marcel Schneider (FZJ), for help with setting up and managing the experiment. Furthermore, we would like to acknowledge our collaboration partners from Deutsches Biomasseforschungszen-trum (DBFZ) for support on chemical analyses. The authors declare that they have no competing interests. Publisher Copyright: © 2017 The Authors. Global Change Biology Bioenergy Published by John Wiley & Sons Ltd.
PY - 2017/10
Y1 - 2017/10
N2 - Low-input grassland biomass from marginal and other slightly more fertile sites can be used for energy production without competing with food or fodder production. The effect of grassland diversity on methane yield has received some attention, but we do not know how community assembly may affect methane yield from grassland biomass. However, methane yields determine the potential economic value of a bioenergy substrate. Hence, a better understanding of how plant community assembly affects methane yield would be important. We measured biomass production and methane yield in the second year of a grassland field experiment which manipulated the order of arrival of different plant functional groups (forbs, grasses or legumes sown first and all sown simultaneously) and sown diversity (9 vs. 21 species). The order of arrival of the plant functional groups significantly determined the relative dominance of each group which in turn mainly explained the variance in aboveground biomass production. Differences in area-specific methane yields were driven by differences in biomass production and which plant functional groups dominated a plot. When grasses were sown first, legumes and grasses codominated a plot and the highest area-specific methane yield was obtained. Overall, the results indicate that altering the order of arrival affected the community functional and species composition (and hence methane yields) much more than sown diversity. Our study shows that a combined use of positive biodiversity effects and guided plant community assembly may be able to optimize methane yields under field conditions. This may allow a guided, sustainable, and lucrative use of grassland biomass for biogas production in the future.
AB - Low-input grassland biomass from marginal and other slightly more fertile sites can be used for energy production without competing with food or fodder production. The effect of grassland diversity on methane yield has received some attention, but we do not know how community assembly may affect methane yield from grassland biomass. However, methane yields determine the potential economic value of a bioenergy substrate. Hence, a better understanding of how plant community assembly affects methane yield would be important. We measured biomass production and methane yield in the second year of a grassland field experiment which manipulated the order of arrival of different plant functional groups (forbs, grasses or legumes sown first and all sown simultaneously) and sown diversity (9 vs. 21 species). The order of arrival of the plant functional groups significantly determined the relative dominance of each group which in turn mainly explained the variance in aboveground biomass production. Differences in area-specific methane yields were driven by differences in biomass production and which plant functional groups dominated a plot. When grasses were sown first, legumes and grasses codominated a plot and the highest area-specific methane yield was obtained. Overall, the results indicate that altering the order of arrival affected the community functional and species composition (and hence methane yields) much more than sown diversity. Our study shows that a combined use of positive biodiversity effects and guided plant community assembly may be able to optimize methane yields under field conditions. This may allow a guided, sustainable, and lucrative use of grassland biomass for biogas production in the future.
KW - Ecosystems Research
KW - biodiversity
KW - bioenergy landscape
KW - biogas
KW - biomethane potential
KW - community assembly
KW - plant functional groups
KW - priority effect
UR - http://www.scopus.com/inward/record.url?scp=85029704458&partnerID=8YFLogxK
U2 - 10.1111/gcbb.12441
DO - 10.1111/gcbb.12441
M3 - Journal articles
VL - 9
SP - 1555
EP - 1562
JO - Global Change Biology : Bioenergy
JF - Global Change Biology : Bioenergy
SN - 1757-1693
IS - 10
ER -