Denitrifying pathways dominate nitrous oxide emissions from managed grassland during drought and rewetting.
Eliza HarrisEugenio Diaz-PinesE StollMichael SchloterStefanie SchulzClara DuffnerKexue LiKatie L MooreJohannes IngrischDavid ReinthalerS Zechmeister-BoltensternStephan GlatzelNicolas BrüggemannMichael BahnPublished in: Science advances (2021)
Nitrous oxide is a powerful greenhouse gas whose atmospheric growth rate has accelerated over the past decade. Most anthropogenic N2O emissions result from soil N fertilization, which is converted to N2O via oxic nitrification and anoxic denitrification pathways. Drought-affected soils are expected to be well oxygenated; however, using high-resolution isotopic measurements, we found that denitrifying pathways dominated N2O emissions during a severe drought applied to managed grassland. This was due to a reversible, drought-induced enrichment in nitrogen-bearing organic matter on soil microaggregates and suggested a strong role for chemo- or codenitrification. Throughout rewetting, denitrification dominated emissions, despite high variability in fluxes. Total N2O flux and denitrification contribution were significantly higher during rewetting than for control plots at the same soil moisture range. The observed feedbacks between precipitation changes induced by climate change and N2O emission pathways are sufficient to account for the accelerating N2O growth rate observed over the past decade.
Keyphrases
- climate change
- plant growth
- microbial community
- organic matter
- wastewater treatment
- high resolution
- arabidopsis thaliana
- human health
- heat stress
- municipal solid waste
- life cycle
- heavy metals
- drug induced
- early onset
- high glucose
- drug delivery
- photodynamic therapy
- endothelial cells
- tandem mass spectrometry
- cancer therapy
- air pollution
- high speed