Plant species identity surpasses species richness as a key driver of N2O emissions from grassland

Plant species identity surpasses species richness as a key driver of N2O emissions from grassland

Grassland ecosystems worldwide not only provide many important ecosystem services but they also function as a major source of the greenhouse gas nitrous oxide (N2O), especially in response to nitrogen deposition by grazing animals. To explore the role of plants as mediators of these emissions, we te...

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Bibliographic Details
Published in:Global change biology Vol. 20; no. 1; pp. 265 - 275
Main Authors: Abalos, Diego, De Deyn, Gerlinde B., Kuyper, Thomas W., van Groenigen, Jan Willem
Format: Journal Article
Language:English
Published: Oxford Blackwell Publishing Ltd 01-01-2014
Wiley-Blackwell
Subjects:
Animal and plant ecology
Animal, plant and microbial ecology
biodiversity
Biological and medical sciences
biomass productivity
carbon sequestration
diversity
Fundamental and applied biological sciences. Psychology
General aspects
grassland
Grasslands
microbial communities
n uptake
nitrogen cycle
Nitrous oxide
plant community composition
plant traits
productivity
rhizosphere
soil
Synecology
Terrestrial ecosystems
traits
urine
Grassland
Productivity
Plant community
nitrous oxide
plant community composition
Biomass
Biodiversity
Nitrogen cycle
Vegetation
Nitrogen protoxide
Species richness
biomass productivity
plant traits
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Summary:Grassland ecosystems worldwide not only provide many important ecosystem services but they also function as a major source of the greenhouse gas nitrous oxide (N2O), especially in response to nitrogen deposition by grazing animals. To explore the role of plants as mediators of these emissions, we tested whether and how N2O emissions are dependent on grass species richness and/or specific grass species composition in the absence and presence of urine deposition. We hypothesized that: (i) N2O emissions relate negatively to plant productivity; (ii) four‐species mixtures have lower emissions than monocultures (as they are expected to be more productive); (iii) emissions are lowest in combinations of species with diverging root morphology and high root biomass; and (iv) the identity of the key species that reduce N2O emissions is dependent on urine deposition. We established monocultures and two‐ and four‐species mixtures of common grass species with diverging functional traits: Lolium perenne L. (Lp), Festuca arundinacea Schreb. (Fa), Phleum pratense L. (Php) and Poa trivialis L. (Pt), and quantified N2O emissions for 42 days. We found no relation between plant species richness and N2O emissions. However, N2O emissions were significantly reduced in specific plant species combinations. In the absence of urine, plant communities of Fa+Php acted as a sink for N2O, whereas the monocultures of these species constituted a N2O source. With urine application Lp+Pt plant communities reduced (P < 0.001) N2O emissions by 44% compared to monocultures of Lp. Reductions in N2O emissions by species mixtures could be explained by total biomass productivity and by complementarity in root morphology. This study shows that plant species composition is a key component underlying N2O emissions from grassland ecosystems. Selection of specific grass species combinations in the context of the expected nitrogen deposition regimes may therefore provide a key for mitigation of N2O emissions.
Bibliography:ArticleID:GCB12350
the Netherlands Organization for Scientific Research/Earth and Life Sciences - No. AGL2009-08412-AGR
EU - No. AGL2009-08412-AGR
istex:CB531437C7F508C0F5679BE43C4300D44D913131
ark:/67375/WNG-818N25QR-N
Spanish Ministry of Science and Innovation
ISSN:1354-1013
1365-2486
DOI:10.1111/gcb.12350