A general framework for nitrogen deposition effects on soil respiration in global forests

Xiaoyu Cen; Peter Vitousek; Nianpeng He; Ben Bond-Lamberty; Shuli Niu; Enzai Du; Kailiang Yu; Mianhai Zheng; Kevin Van Sundert; Elizabeth L. Paulus; Liyin He; Li Xu; Mingxu Li; Klaus Butterbach-Bahl

doi:10.1038/s41467-025-67203-8

A general framework for nitrogen deposition effects on soil respiration in global forests

Xiaoyu Cen
, Peter Vitousek
, Nianpeng He
, Ben Bond-Lamberty
, Shuli Niu
, Enzai Du
, Kailiang Yu
, Mianhai Zheng
, Kevin Van Sundert
, Elizabeth L. Paulus
, Liyin He
, Li Xu
, Mingxu Li
, Klaus Butterbach-Bahl

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Since the Industrial Revolution, human activities have altered atmospheric nitrogen (N) deposition to global forests, affecting carbon dioxide emissions from soils (soil respiration or SR) – one of the largest land-atmosphere carbon fluxes. However, experimental studies have demonstrated both positive and negative effects of N deposition on SR in global forests, leading to debates on how N deposition increases or decreases SR. We developed a framework for generalizing SR responses to N deposition using synthesized data from 168 N addition experiments worldwide and observed SR across the global natural N deposition gradient. The findings indicate that N deposition decreased SR in 2.9% of global forested areas, particularly in eastern China, western Europe, and the eastern USA. However, the net effect of N deposition increased the global forest SR by ~5% (1.7 ± 0.1 PgC yr^–1). If N pollution could be effectively controlled, global forest SR would decrease, potentially contributing to a reduction in the terrestrial carbon emissions.

Original language	English
Article number	506
Number of pages	16
Journal	Nature Communications
Volume	17
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-67203-8
Publication status	Published - 14 Jan 2026

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Cite this

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title = "A general framework for nitrogen deposition effects on soil respiration in global forests",

abstract = "Since the Industrial Revolution, human activities have altered atmospheric nitrogen (N) deposition to global forests, affecting carbon dioxide emissions from soils (soil respiration or SR) – one of the largest land-atmosphere carbon fluxes. However, experimental studies have demonstrated both positive and negative effects of N deposition on SR in global forests, leading to debates on how N deposition increases or decreases SR. We developed a framework for generalizing SR responses to N deposition using synthesized data from 168 N addition experiments worldwide and observed SR across the global natural N deposition gradient. The findings indicate that N deposition decreased SR in 2.9\% of global forested areas, particularly in eastern China, western Europe, and the eastern USA. However, the net effect of N deposition increased the global forest SR by \textasciitilde{}5\% (1.7 ± 0.1 PgC yr–1). If N pollution could be effectively controlled, global forest SR would decrease, potentially contributing to a reduction in the terrestrial carbon emissions.",

author = "Xiaoyu Cen and Peter Vitousek and Nianpeng He and Ben Bond-Lamberty and Shuli Niu and Enzai Du and Kailiang Yu and Mianhai Zheng and \{Van Sundert\}, Kevin and Paulus, \{Elizabeth L.\} and Liyin He and Li Xu and Mingxu Li and Klaus Butterbach-Bahl",

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doi = "10.1038/s41467-025-67203-8",

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T1 - A general framework for nitrogen deposition effects on soil respiration in global forests

AU - Cen, Xiaoyu

AU - Vitousek, Peter

AU - He, Nianpeng

AU - Bond-Lamberty, Ben

AU - Niu, Shuli

AU - Du, Enzai

AU - Yu, Kailiang

AU - Zheng, Mianhai

AU - Van Sundert, Kevin

AU - Paulus, Elizabeth L.

AU - He, Liyin

AU - Xu, Li

AU - Li, Mingxu

AU - Butterbach-Bahl, Klaus

PY - 2026/1/14

Y1 - 2026/1/14

N2 - Since the Industrial Revolution, human activities have altered atmospheric nitrogen (N) deposition to global forests, affecting carbon dioxide emissions from soils (soil respiration or SR) – one of the largest land-atmosphere carbon fluxes. However, experimental studies have demonstrated both positive and negative effects of N deposition on SR in global forests, leading to debates on how N deposition increases or decreases SR. We developed a framework for generalizing SR responses to N deposition using synthesized data from 168 N addition experiments worldwide and observed SR across the global natural N deposition gradient. The findings indicate that N deposition decreased SR in 2.9% of global forested areas, particularly in eastern China, western Europe, and the eastern USA. However, the net effect of N deposition increased the global forest SR by ~5% (1.7 ± 0.1 PgC yr–1). If N pollution could be effectively controlled, global forest SR would decrease, potentially contributing to a reduction in the terrestrial carbon emissions.

AB - Since the Industrial Revolution, human activities have altered atmospheric nitrogen (N) deposition to global forests, affecting carbon dioxide emissions from soils (soil respiration or SR) – one of the largest land-atmosphere carbon fluxes. However, experimental studies have demonstrated both positive and negative effects of N deposition on SR in global forests, leading to debates on how N deposition increases or decreases SR. We developed a framework for generalizing SR responses to N deposition using synthesized data from 168 N addition experiments worldwide and observed SR across the global natural N deposition gradient. The findings indicate that N deposition decreased SR in 2.9% of global forested areas, particularly in eastern China, western Europe, and the eastern USA. However, the net effect of N deposition increased the global forest SR by ~5% (1.7 ± 0.1 PgC yr–1). If N pollution could be effectively controlled, global forest SR would decrease, potentially contributing to a reduction in the terrestrial carbon emissions.

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DO - 10.1038/s41467-025-67203-8

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VL - 17

JO - Nature Communications

JF - Nature Communications

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M1 - 506

ER -

A general framework for nitrogen deposition effects on soil respiration in global forests

Abstract

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