Warming and redistribution of nitrogen inputs drive an increase in terrestrial nitrous oxide emission factor

Eliza Harris; L. Yu; yingping wang; Joachim Mohn; Stephan Henne; E Bai; M Barthel; M Bauters; Pascal Boeckx; Chris Dorich; Mark Farrell; Paul Krummel; Zoe Loh; Markus Reichstein; Johan Six; Martin Steinbacher; Naomi Wells; Michael Bahn; Peter Rayner

doi:10.1038/s41467-022-32001-z

Warming and redistribution of nitrogen inputs drive an increase in terrestrial nitrous oxide emission factor

Eliza Harris, L. Yu, yingping wang, Joachim Mohn, Stephan Henne, E Bai, M Barthel, M Bauters, Pascal Boeckx, Chris Dorich, Mark Farrell, Paul Krummel, Zoe Loh, Markus Reichstein, Johan Six, Martin Steinbacher, Naomi Wells, Michael Bahn, Peter Rayner

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Abstract

Anthropogenic nitrogen inputs cause major negative environmental impacts, including emissions of the important greenhouse gas N2O. Despite their importance, shifts in terrestrial N loss pathways driven by global change are highly uncertain. Here we present a coupled soil-atmosphere isotope model (IsoTONE) to quantify terrestrial N losses and N2O emission factors from 1850-2020. We find that N inputs from atmospheric deposition caused 51% of anthropogenic N2O emissions from soils in 2020. The mean effective global emission factor for N2O was 4.3 ± 0.3% in 2020 (weighted by N inputs), much higher than the surface area-weighted mean (1.1 ± 0.1%). Climate change and spatial redistribution of fertilisation N inputs have driven an increase in global emission factor over the past century, which accounts for 18% of the anthropogenic soil flux in 2020. Predicted increases in fertilisation in emerging economies will accelerate N2O-driven climate warming in coming decades, unless targeted mitigation measures are introduced.

Original language	English
Article number	4310
Journal	Nature Communications
Volume	13
Issue number	1
DOIs	https://doi.org/10.1038/s41467-022-32001-z
Publication status	Published - Dec 2022
Externally published	Yes

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Harris, E., Yu, L., wang, Y., Mohn, J., Henne, S., Bai, E., Barthel, M., Bauters, M., Boeckx, P., Dorich, C., Farrell, M., Krummel, P., Loh, Z., Reichstein, M., Six, J., Steinbacher, M., Wells, N., Bahn, M., & Rayner, P. (2022). Warming and redistribution of nitrogen inputs drive an increase in terrestrial nitrous oxide emission factor. Nature Communications, 13(1), Article 4310. https://doi.org/10.1038/s41467-022-32001-z

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title = "Warming and redistribution of nitrogen inputs drive an increase in terrestrial nitrous oxide emission factor",

abstract = "Anthropogenic nitrogen inputs cause major negative environmental impacts, including emissions of the important greenhouse gas N2O. Despite their importance, shifts in terrestrial N loss pathways driven by global change are highly uncertain. Here we present a coupled soil-atmosphere isotope model (IsoTONE) to quantify terrestrial N losses and N2O emission factors from 1850-2020. We find that N inputs from atmospheric deposition caused 51\% of anthropogenic N2O emissions from soils in 2020. The mean effective global emission factor for N2O was 4.3 ± 0.3\% in 2020 (weighted by N inputs), much higher than the surface area-weighted mean (1.1 ± 0.1\%). Climate change and spatial redistribution of fertilisation N inputs have driven an increase in global emission factor over the past century, which accounts for 18\% of the anthropogenic soil flux in 2020. Predicted increases in fertilisation in emerging economies will accelerate N2O-driven climate warming in coming decades, unless targeted mitigation measures are introduced.",

author = "Eliza Harris and L. Yu and yingping wang and Joachim Mohn and Stephan Henne and E Bai and M Barthel and M Bauters and Pascal Boeckx and Chris Dorich and Mark Farrell and Paul Krummel and Zoe Loh and Markus Reichstein and Johan Six and Martin Steinbacher and Naomi Wells and Michael Bahn and Peter Rayner",

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Harris, E, Yu, L, wang, Y, Mohn, J, Henne, S, Bai, E, Barthel, M, Bauters, M, Boeckx, P, Dorich, C, Farrell, M, Krummel, P, Loh, Z, Reichstein, M, Six, J, Steinbacher, M, Wells, N, Bahn, M & Rayner, P 2022, 'Warming and redistribution of nitrogen inputs drive an increase in terrestrial nitrous oxide emission factor', Nature Communications, vol. 13, no. 1, 4310. https://doi.org/10.1038/s41467-022-32001-z

TY - JOUR

T1 - Warming and redistribution of nitrogen inputs drive an increase in terrestrial nitrous oxide emission factor

AU - Harris, Eliza

AU - Yu, L.

AU - wang, yingping

AU - Mohn, Joachim

AU - Henne, Stephan

AU - Bai, E

AU - Barthel, M

AU - Bauters, M

AU - Boeckx, Pascal

AU - Dorich, Chris

AU - Farrell, Mark

AU - Krummel, Paul

AU - Loh, Zoe

AU - Reichstein, Markus

AU - Six, Johan

AU - Steinbacher, Martin

AU - Wells, Naomi

AU - Bahn, Michael

AU - Rayner, Peter

PY - 2022/12

Y1 - 2022/12

N2 - Anthropogenic nitrogen inputs cause major negative environmental impacts, including emissions of the important greenhouse gas N2O. Despite their importance, shifts in terrestrial N loss pathways driven by global change are highly uncertain. Here we present a coupled soil-atmosphere isotope model (IsoTONE) to quantify terrestrial N losses and N2O emission factors from 1850-2020. We find that N inputs from atmospheric deposition caused 51% of anthropogenic N2O emissions from soils in 2020. The mean effective global emission factor for N2O was 4.3 ± 0.3% in 2020 (weighted by N inputs), much higher than the surface area-weighted mean (1.1 ± 0.1%). Climate change and spatial redistribution of fertilisation N inputs have driven an increase in global emission factor over the past century, which accounts for 18% of the anthropogenic soil flux in 2020. Predicted increases in fertilisation in emerging economies will accelerate N2O-driven climate warming in coming decades, unless targeted mitigation measures are introduced.

AB - Anthropogenic nitrogen inputs cause major negative environmental impacts, including emissions of the important greenhouse gas N2O. Despite their importance, shifts in terrestrial N loss pathways driven by global change are highly uncertain. Here we present a coupled soil-atmosphere isotope model (IsoTONE) to quantify terrestrial N losses and N2O emission factors from 1850-2020. We find that N inputs from atmospheric deposition caused 51% of anthropogenic N2O emissions from soils in 2020. The mean effective global emission factor for N2O was 4.3 ± 0.3% in 2020 (weighted by N inputs), much higher than the surface area-weighted mean (1.1 ± 0.1%). Climate change and spatial redistribution of fertilisation N inputs have driven an increase in global emission factor over the past century, which accounts for 18% of the anthropogenic soil flux in 2020. Predicted increases in fertilisation in emerging economies will accelerate N2O-driven climate warming in coming decades, unless targeted mitigation measures are introduced.

UR - https://www.scopus.com/pages/publications/85134722389

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DO - 10.1038/s41467-022-32001-z

M3 - Article

C2 - 35879348

SN - 2041-1723

VL - 13

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 4310

ER -

Warming and redistribution of nitrogen inputs drive an increase in terrestrial nitrous oxide emission factor

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