Above canopy and understory nitrogen additions lead to divergent spatio-temporal nitrogen retention patterns in a temperate forest

Zhichun Yang; Rossella Guerrieri; Nan Ye; Yilin Shao; Fei Yu; Tiezhu Jiao; Huichun Yang; Ji Chen; Mianhai Zheng; Ang Wang; Qiulong Yin; Zhanqing Hao; Qiong Chen; Zuoqiang Yuan

doi:10.1038/s43247-026-03313-5

Above canopy and understory nitrogen additions lead to divergent spatio-temporal nitrogen retention patterns in a temperate forest

Zhichun Yang
, Rossella Guerrieri
, Nan Ye
, Yilin Shao
, Fei Yu
, Tiezhu Jiao
, Huichun Yang
, Ji Chen
, Mianhai Zheng
, Ang Wang
, Qiulong Yin
, Zhanqing Hao
, Qiong Chen
, Zuoqiang Yuan

University of Bologna
Northwestern Polytechnical University Xian
CAS - Institute of Earth Environment
CAS - South China Institute of Botany
CAS - Shenyang Institute of Applied Ecology
Shaanxi Normal University

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

Abstract

Forest ecosystem responses to nitrogen (N) deposition depend on N fate, yet most simulated N deposition experiments focus on understory addition, overlooking canopy N processes. Here we compared canopy (CAN) and understory (UAN) N addition in a secondary forest using a ¹⁵N tracer approach, adding ¹⁵N as ¹⁵NO₃^- or ¹⁵NH₄⁺. Total ¹⁵N recovery was higher under UAN than CAN initially, but recoveries converged by day 365. CAN increased long-term N retention in woody biomass, with stems becoming the dominant sink, accounting for up to 34.9% of ¹⁵N recovered after one year. UAN promoted short-term N retention in understory layer and long-term N retention in soil. ¹⁵N recovery increased with soil depth under CAN but decreased under UAN from 120 to 365 days. Trees absorbed more ¹⁵NO₃^- than ¹⁵NH₄⁺, whereas soil retained the two forms similarly. These findings indicate that N manipulation methods affect N retention magnitude and spatial distribution.

Original language	English
Article number	316
Journal	Communications Earth and Environment
Volume	7
Issue number	1
DOIs	https://doi.org/10.1038/s43247-026-03313-5
State	Published - Dec 2026

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Yang, Z., Guerrieri, R., Ye, N., Shao, Y., Yu, F., Jiao, T., Yang, H., Chen, J., Zheng, M., Wang, A., Yin, Q., Hao, Z., Chen, Q., & Yuan, Z. (2026). Above canopy and understory nitrogen additions lead to divergent spatio-temporal nitrogen retention patterns in a temperate forest. Communications Earth and Environment, 7(1), Article 316. https://doi.org/10.1038/s43247-026-03313-5

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title = "Above canopy and understory nitrogen additions lead to divergent spatio-temporal nitrogen retention patterns in a temperate forest",

abstract = "Forest ecosystem responses to nitrogen (N) deposition depend on N fate, yet most simulated N deposition experiments focus on understory addition, overlooking canopy N processes. Here we compared canopy (CAN) and understory (UAN) N addition in a secondary forest using a 15N tracer approach, adding 15N as 15NO3- or 15NH4+. Total 15N recovery was higher under UAN than CAN initially, but recoveries converged by day 365. CAN increased long-term N retention in woody biomass, with stems becoming the dominant sink, accounting for up to 34.9\% of 15N recovered after one year. UAN promoted short-term N retention in understory layer and long-term N retention in soil. 15N recovery increased with soil depth under CAN but decreased under UAN from 120 to 365 days. Trees absorbed more 15NO3- than 15NH4+, whereas soil retained the two forms similarly. These findings indicate that N manipulation methods affect N retention magnitude and spatial distribution.",

author = "Zhichun Yang and Rossella Guerrieri and Nan Ye and Yilin Shao and Fei Yu and Tiezhu Jiao and Huichun Yang and Ji Chen and Mianhai Zheng and Ang Wang and Qiulong Yin and Zhanqing Hao and Qiong Chen and Zuoqiang Yuan",

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doi = "10.1038/s43247-026-03313-5",

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T1 - Above canopy and understory nitrogen additions lead to divergent spatio-temporal nitrogen retention patterns in a temperate forest

AU - Yang, Zhichun

AU - Guerrieri, Rossella

AU - Ye, Nan

AU - Shao, Yilin

AU - Yu, Fei

AU - Jiao, Tiezhu

AU - Yang, Huichun

AU - Chen, Ji

AU - Zheng, Mianhai

AU - Wang, Ang

AU - Yin, Qiulong

AU - Hao, Zhanqing

AU - Chen, Qiong

AU - Yuan, Zuoqiang

PY - 2026/12

Y1 - 2026/12

N2 - Forest ecosystem responses to nitrogen (N) deposition depend on N fate, yet most simulated N deposition experiments focus on understory addition, overlooking canopy N processes. Here we compared canopy (CAN) and understory (UAN) N addition in a secondary forest using a 15N tracer approach, adding 15N as 15NO3- or 15NH4+. Total 15N recovery was higher under UAN than CAN initially, but recoveries converged by day 365. CAN increased long-term N retention in woody biomass, with stems becoming the dominant sink, accounting for up to 34.9% of 15N recovered after one year. UAN promoted short-term N retention in understory layer and long-term N retention in soil. 15N recovery increased with soil depth under CAN but decreased under UAN from 120 to 365 days. Trees absorbed more 15NO3- than 15NH4+, whereas soil retained the two forms similarly. These findings indicate that N manipulation methods affect N retention magnitude and spatial distribution.

AB - Forest ecosystem responses to nitrogen (N) deposition depend on N fate, yet most simulated N deposition experiments focus on understory addition, overlooking canopy N processes. Here we compared canopy (CAN) and understory (UAN) N addition in a secondary forest using a 15N tracer approach, adding 15N as 15NO3- or 15NH4+. Total 15N recovery was higher under UAN than CAN initially, but recoveries converged by day 365. CAN increased long-term N retention in woody biomass, with stems becoming the dominant sink, accounting for up to 34.9% of 15N recovered after one year. UAN promoted short-term N retention in understory layer and long-term N retention in soil. 15N recovery increased with soil depth under CAN but decreased under UAN from 120 to 365 days. Trees absorbed more 15NO3- than 15NH4+, whereas soil retained the two forms similarly. These findings indicate that N manipulation methods affect N retention magnitude and spatial distribution.

UR - https://www.scopus.com/pages/publications/105035862013

U2 - 10.1038/s43247-026-03313-5

DO - 10.1038/s43247-026-03313-5

M3 - 文章

AN - SCOPUS:105035862013

SN - 2662-4435

VL - 7

JO - Communications Earth and Environment

JF - Communications Earth and Environment

IS - 1

M1 - 316

ER -

Above canopy and understory nitrogen additions lead to divergent spatio-temporal nitrogen retention patterns in a temperate forest

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