Global terrestrial nitrogen fixation and its modification by agriculture

Carla R. Reis Ely; Steven Perakis; Cory C. Cleveland; Duncan Menge; Sasha Reed; Benton Taylor; Sarah A. Batterman; Christopher M. Clark; Timothy E. Crews; Katherine A Dynarski; Maga G. Gei; Michael J. Gundale; David F. Herridge; Sarah E. Jovan; Sian Kou-Giesbrecht; Mark B. Peoples; Johannes Piipponen; Emilio Rodriguez-Caballero; Verity G. Salmon; Fiona M. Soper; Anika P. Staccone; Bettina Weber; Christopher A. Williams; Nina Wurzburger

doi:10.1038/s41586-025-09201-w

Global terrestrial nitrogen fixation and its modification by agriculture

Nature

By: Carla R. Reis Ely, Steven Perakis, Cory C. Cleveland, Duncan Menge, Sasha Reed, Benton Taylor, Sarah A. Batterman, Christopher M. Clark, Timothy E. Crews, Katherine A Dynarski, Maga G. Gei, Michael J. Gundale, David F. Herridge, Sarah E. Jovan, Sian Kou-Giesbrecht, Mark B. Peoples, Johannes Piipponen, Emilio Rodriguez-Caballero, Verity G. Salmon, Fiona M. Soper, Anika P. Staccone, Bettina Weber, Christopher A. Williams, and Nina Wurzburger

https://doi.org/10.1038/s41586-025-09201-w

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Abstract

Biological nitrogen fixation (BNF) is the largest natural source of new nitrogen (N) that supports terrestrial productivity^1,2, yet estimates of global terrestrial BNF remain highly uncertain^3,4. Here we show that this uncertainty is partly because of sampling bias, as field BNF measurements in natural terrestrial ecosystems occur where N fixers are 17 times more prevalent than their mean abundances worldwide. To correct this bias, we develop new estimates of global terrestrial BNF by upscaling field BNF measurements using spatially explicit abundances of all major biogeochemical N-fixing niches. We find that natural biomes sustain lower BNF, 65 (52–77) Tg N yr⁻¹, than previous empirical bottom-up estimates^3,4, with most BNF occurring in tropical forests and drylands. We also find high agricultural BNF in croplands and cultivated pastures, 56 (54–58) Tg N yr⁻¹. Agricultural BNF has increased terrestrial BNF by 64% and total terrestrial N inputs from all sources by 60% over pre-industrial levels. Our results indicate that BNF may impose stronger constraints on the carbon sink in natural terrestrial biomes and represent a larger source of agricultural N than is generally considered in analyses of the global N cycle^5,6, with implications for proposed safe operating limits for N use^7,8.

Additional publication details
Publication type	Article
Publication Subtype	Journal Article
Title	Global terrestrial nitrogen fixation and its modification by agriculture
Series title	Nature
DOI	10.1038/s41586-025-09201-w
Volume	643
Publication Date	July 16, 2025
Year Published	2025
Language	English
Publisher	Nature
Contributing office(s)	Forest and Rangeland Ecosystem Science Center
Description	7 p.
First page	705
Last page	711