Spatial changes in nitrogen inputs drive short- and long-term variability in global nitrous oxide emissions
- 1University of Innsbruck, Institute of Ecology, Plant, Soil and Ecosystem Processes, Innsbruck, Austria (eliza.harris@uibk.ac.at)
- 2Laboratory for Air Pollution & Environmental Technology, Empa, Switzerland
- 3CSIRO Ocean and Atmosphere, VIC, Australia
- 4Institute of Applied Ecology, Chinese Academy of Sciences, China
- 5Department of Environmental Systems Science, ETH Zurich, Switzerland
- 6Isotope Bioscience Laboratory, ISOFYS, Ghent University, Belgium
- 7Natural Resource Ecology Laboratory, Colorado State University, USA
- 8CSIRO Agriculture and Food, SA, Australia
- 9Centre for Coastal Biogeochemistry, Southern Cross University, Australia
- 10Department of Earth Sciences, University of Melbourne, VIC, Australia
- 11Institute of Groundwater and Earth Sciences, Jinan University, China
Anthropogenic activities, particularly fertilisation, have resulted in significant increases in reactive nitrogen (rN) in soils globally, leading to eutrophication, acidification, poor air quality, and emissions of the important greenhouse gas N2O. Understanding the partitioning of rN losses into different environmental compartments is critical to mitigate negative impacts, however, loss pathways are poorly quantified, and potential changes driven by climate warming and societal shifts are highly uncertain. We present a coupled soil-atmosphere isotope model (IsoTONE; ISOtopic Tracing Of Nitrogen in the Environment) to partition rN losses into leaching, harvest, NH3 volatilization, and production of NO, N2 and N2O based on a global dataset of soil δ15N, as well as numerous other geoclimatic and experimental datasets. The model was optimized in a Bayesian framework using a time series of N2O mixing ratios and isotopic compositions since the preindustrial era, as well as a global dataset of N2O emission factors (EF). The posterior model results showed that the total anthropogenic flux in 2020 (7.8 Tg N2O-N a-1) was dominated by indirect emissions resulting from N deposition, while the growth rate and trend in anthropogenic N2O was driven by both direct N fertilisation and deposition inputs. In contrast, inputs from fixation N drive natural N2O emissions, and were responsible for subdecadal interannual variability in total emissions.
Total N gas (N2O + NO + N2) production and N2O losses were strongly dependent on geoclimate and thus spatially variable, therefore the spatial pattern of N inputs strongly impacted resulting EFs and total N2O emissions. The area-weighted global EF for N2O was 1% of anthropogenic N inputs in 2020, similar to the current IPCC default of 1.4%, however the N input-weighted global EF was 4.3%. Shifts in fertilisation inputs from the temperate Northern hemisphere towards warmer regions with higher EFs such as India and China have led to accelerating N2O emissions (1.02±0.7 Tg N2O-N a-1). In addition, N2O emissions have increased over the past decades due to climate warming (0.76±0.4 Tg N2O-N a-1). Predicted increases in fertilisation in India and Africa in the coming decades could further accelerate N2O-driven climate warming, unless mitigation measures are implemented to increase fertiliser N use efficiency and reduce N2O emission factors.
How to cite: Harris, E., Yu, L., Wang, Y. P., Mohn, J., Bai, E., Barthel, M., Six, J., Bauters, M., Boeckx, P., Dorich, C., Farrell, M., Henne, S., Krummel, P., Loh, Z., Steinbacher, M., Zellweger, C., Wells, N. S., Bahn, M., and Rayner, P.: Spatial changes in nitrogen inputs drive short- and long-term variability in global nitrous oxide emissions, EGU General Assembly 2021, online, 19–30 Apr 2021, EGU21-804, https://doi.org/10.5194/egusphere-egu21-804, 2021.
