Canadian net forest CO2 uptake enhanced by heat drought via reduced respiration

Guanyu Dong; Fei Jiang; Yongguang Zhang; Weimin Ju; Shilong Piao; Philippe Ciais; Wouter Peters; Ingrid T. Luijkx; Junjie Liu; Frédéric Chevallier; Ning Zeng; Xiangjun Tian; Shamil Maksyutov; Oliver Sonnentag; M. Altaf Arain; Alan G. Barr; Yuanyuan Huang; Chao Yue; Wenping Yuan; Liangyun Liu; Lei Fan; Xu Yue; Jingfeng Xiao; Xing Li; Stephen Sitch; Pierre Friedlingstein; Michael O’Sullivan; Jürgen Knauer; Vivek Arora; Daniel Kennedy; Lei Ma; Peter E. Thornton; Roland Séférian; Tobias Nützel; Jens Heinke; Qing Sun; Sönke Zaehle; Philippe Peylin; Etsushi Kato; Haley Alcock; Bruno Lecavalier; Mousong Wu; Jun Wang; Lingyu Zhang; Guoyuan Lv; Yuanyuan Zhang; Dayang Zhao; Jing M. Chen

doi:10.1038/s41561-025-01875-1

Canadian net forest CO₂ uptake enhanced by heat drought via reduced respiration

Guanyu Dong
, Fei Jiang
, Yongguang Zhang
, Weimin Ju
, Shilong Piao
, Philippe Ciais
, Wouter Peters
, Ingrid T. Luijkx
, Junjie Liu
, Frédéric Chevallier
, Ning Zeng
, Xiangjun Tian
, Shamil Maksyutov
, Oliver Sonnentag
, M. Altaf Arain
, Alan G. Barr
, Yuanyuan Huang
, Chao Yue
, Wenping Yuan
, Liangyun Liu

Lei Fan, Xu Yue, Jingfeng Xiao, Xing Li, Stephen Sitch, Pierre Friedlingstein, Michael O’Sullivan, Jürgen Knauer, Vivek Arora, Daniel Kennedy, Lei Ma, Peter E. Thornton, Roland Séférian, Tobias Nützel, Jens Heinke, Qing Sun, Sönke Zaehle, Philippe Peylin, Etsushi Kato, Haley Alcock, Bruno Lecavalier, Mousong Wu, Jun Wang, Lingyu Zhang, Guoyuan Lv, Yuanyuan Zhang, Dayang Zhao, Jing M. Chen

Nanjing University
Nanjing Normal University
Peking University
Université Versailles St-Quentin
Wageningen University & Research
California Institute of Technology
University of Maryland, College Park
Chinese Academy of Sciences
National Institute for Environmental Studies of Japan
University of Montreal
McMaster University
University of Saskatchewan
CAS - Institute of Geographical Sciences and Natural Resources Research
Northwest Agriculture and Forestry University
CAS - Aerospace Information Research Institute
Southwest University
Nanjing University of Information Science & Technology
University of New Hampshire
Sun Yat-Sen University
University of Exeter
École normale supérieure
Western Sydney University
University of Technology Sydney
Université Laval and Environment and Climate Change Canada
National Center for Atmospheric Research
Oak Ridge National Laboratory
Paul Sabatier University
Ludwig Maximilian University of Munich
Leibniz Association
University of Bern
Max Planck Institute for Biogeochemistry
The Institute of Applied Energy
University of Toronto
Fujian Normal University

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

2 Scopus citations

Abstract

The response of net forest carbon uptake to warm extremes remains elusive. The year 2023 was at the time ‘the hottest year on record’ globally, with Canada’s forests experiencing warm anomalies of above 2 °C and unprecedented drought and wildfires, providing a unique case to examine the response of boreal forest net carbon uptake to climate extremes. Here we combine satellite-based atmospheric CO₂ flux inversions with ground-based in situ observations of CO₂ fluxes and concentrations to investigate Canada’s forest net carbon uptake and its underlying mechanisms in 2023. We find that, compared with 2015–2022, Canada’s forest net carbon uptake was enhanced by 0.28 ± 0.23 PgC, offsetting 38–48% of Canadian wildfire emissions in 2023. This enhanced net uptake was dominated by large ecosystem respiration reductions, mainly attributable to severe root-zone soil moisture deficits and the unimodal temperature response of respiration. However, most dynamic global vegetation models failed to simulate the respiration reductions and the responses to hydrothermal conditions well. This study improves our understanding of boreal forest net carbon uptake in response to climate extremes and highlights an urgent need to improve vegetation models under global warming.

Original language	English
Pages (from-to)	145-152
Number of pages	8
Journal	Nature Geoscience
Volume	19
Issue number	2
DOIs	https://doi.org/10.1038/s41561-025-01875-1
State	Published - Feb 2026
Externally published	Yes

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10.1038/s41561-025-01875-1

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Dong, G., Jiang, F., Zhang, Y., Ju, W., Piao, S., Ciais, P., Peters, W., Luijkx, I. T., Liu, J., Chevallier, F., Zeng, N., Tian, X., Maksyutov, S., Sonnentag, O., Arain, M. A., Barr, A. G., Huang, Y., Yue, C., Yuan, W., ... Chen, J. M. (2026). Canadian net forest CO₂ uptake enhanced by heat drought via reduced respiration. Nature Geoscience, 19(2), 145-152. https://doi.org/10.1038/s41561-025-01875-1

@article{b44241fec2194789b10f79b76a938a23,

title = "Canadian net forest CO2 uptake enhanced by heat drought via reduced respiration",

abstract = "The response of net forest carbon uptake to warm extremes remains elusive. The year 2023 was at the time {\textquoteleft}the hottest year on record{\textquoteright} globally, with Canada{\textquoteright}s forests experiencing warm anomalies of above 2 °C and unprecedented drought and wildfires, providing a unique case to examine the response of boreal forest net carbon uptake to climate extremes. Here we combine satellite-based atmospheric CO2 flux inversions with ground-based in situ observations of CO2 fluxes and concentrations to investigate Canada{\textquoteright}s forest net carbon uptake and its underlying mechanisms in 2023. We find that, compared with 2015–2022, Canada{\textquoteright}s forest net carbon uptake was enhanced by 0.28 ± 0.23 PgC, offsetting 38–48\% of Canadian wildfire emissions in 2023. This enhanced net uptake was dominated by large ecosystem respiration reductions, mainly attributable to severe root-zone soil moisture deficits and the unimodal temperature response of respiration. However, most dynamic global vegetation models failed to simulate the respiration reductions and the responses to hydrothermal conditions well. This study improves our understanding of boreal forest net carbon uptake in response to climate extremes and highlights an urgent need to improve vegetation models under global warming.",

author = "Guanyu Dong and Fei Jiang and Yongguang Zhang and Weimin Ju and Shilong Piao and Philippe Ciais and Wouter Peters and Luijkx, \{Ingrid T.\} and Junjie Liu and Fr{\'e}d{\'e}ric Chevallier and Ning Zeng and Xiangjun Tian and Shamil Maksyutov and Oliver Sonnentag and Arain, \{M. Altaf\} and Barr, \{Alan G.\} and Yuanyuan Huang and Chao Yue and Wenping Yuan and Liangyun Liu and Lei Fan and Xu Yue and Jingfeng Xiao and Xing Li and Stephen Sitch and Pierre Friedlingstein and Michael O{\textquoteright}Sullivan and J{\"u}rgen Knauer and Vivek Arora and Daniel Kennedy and Lei Ma and Thornton, \{Peter E.\} and Roland S{\'e}f{\'e}rian and Tobias N{\"u}tzel and Jens Heinke and Qing Sun and S{\"o}nke Zaehle and Philippe Peylin and Etsushi Kato and Haley Alcock and Bruno Lecavalier and Mousong Wu and Jun Wang and Lingyu Zhang and Guoyuan Lv and Yuanyuan Zhang and Dayang Zhao and Chen, \{Jing M.\}",

note = "Publisher Copyright: {\textcopyright} The Author(s), under exclusive licence to Springer Nature Limited 2026.",

year = "2026",

month = feb,

doi = "10.1038/s41561-025-01875-1",

language = "English",

volume = "19",

pages = "145--152",

journal = "Nature Geoscience",

issn = "1752-0894",

publisher = "Nature Publishing Group",

number = "2",

}

Dong, G, Jiang, F, Zhang, Y, Ju, W, Piao, S, Ciais, P, Peters, W, Luijkx, IT, Liu, J, Chevallier, F, Zeng, N, Tian, X, Maksyutov, S, Sonnentag, O, Arain, MA, Barr, AG, Huang, Y, Yue, C, Yuan, W, Liu, L, Fan, L, Yue, X, Xiao, J, Li, X, Sitch, S, Friedlingstein, P, O’Sullivan, M, Knauer, J, Arora, V, Kennedy, D, Ma, L, Thornton, PE, Séférian, R, Nützel, T, Heinke, J, Sun, Q, Zaehle, S, Peylin, P, Kato, E, Alcock, H, Lecavalier, B, Wu, M, Wang, J, Zhang, L, Lv, G, Zhang, Y, Zhao, D & Chen, JM 2026, 'Canadian net forest CO₂ uptake enhanced by heat drought via reduced respiration', Nature Geoscience, vol. 19, no. 2, pp. 145-152. https://doi.org/10.1038/s41561-025-01875-1

TY - JOUR

T1 - Canadian net forest CO2 uptake enhanced by heat drought via reduced respiration

AU - Dong, Guanyu

AU - Jiang, Fei

AU - Zhang, Yongguang

AU - Ju, Weimin

AU - Piao, Shilong

AU - Ciais, Philippe

AU - Peters, Wouter

AU - Luijkx, Ingrid T.

AU - Liu, Junjie

AU - Chevallier, Frédéric

AU - Zeng, Ning

AU - Tian, Xiangjun

AU - Maksyutov, Shamil

AU - Sonnentag, Oliver

AU - Arain, M. Altaf

AU - Barr, Alan G.

AU - Huang, Yuanyuan

AU - Yue, Chao

AU - Yuan, Wenping

AU - Liu, Liangyun

AU - Fan, Lei

AU - Yue, Xu

AU - Xiao, Jingfeng

AU - Li, Xing

AU - Sitch, Stephen

AU - Friedlingstein, Pierre

AU - O’Sullivan, Michael

AU - Knauer, Jürgen

AU - Arora, Vivek

AU - Kennedy, Daniel

AU - Ma, Lei

AU - Thornton, Peter E.

AU - Séférian, Roland

AU - Nützel, Tobias

AU - Heinke, Jens

AU - Sun, Qing

AU - Zaehle, Sönke

AU - Peylin, Philippe

AU - Kato, Etsushi

AU - Alcock, Haley

AU - Lecavalier, Bruno

AU - Wu, Mousong

AU - Wang, Jun

AU - Zhang, Lingyu

AU - Lv, Guoyuan

AU - Zhang, Yuanyuan

AU - Zhao, Dayang

AU - Chen, Jing M.

PY - 2026/2

Y1 - 2026/2

N2 - The response of net forest carbon uptake to warm extremes remains elusive. The year 2023 was at the time ‘the hottest year on record’ globally, with Canada’s forests experiencing warm anomalies of above 2 °C and unprecedented drought and wildfires, providing a unique case to examine the response of boreal forest net carbon uptake to climate extremes. Here we combine satellite-based atmospheric CO2 flux inversions with ground-based in situ observations of CO2 fluxes and concentrations to investigate Canada’s forest net carbon uptake and its underlying mechanisms in 2023. We find that, compared with 2015–2022, Canada’s forest net carbon uptake was enhanced by 0.28 ± 0.23 PgC, offsetting 38–48% of Canadian wildfire emissions in 2023. This enhanced net uptake was dominated by large ecosystem respiration reductions, mainly attributable to severe root-zone soil moisture deficits and the unimodal temperature response of respiration. However, most dynamic global vegetation models failed to simulate the respiration reductions and the responses to hydrothermal conditions well. This study improves our understanding of boreal forest net carbon uptake in response to climate extremes and highlights an urgent need to improve vegetation models under global warming.

AB - The response of net forest carbon uptake to warm extremes remains elusive. The year 2023 was at the time ‘the hottest year on record’ globally, with Canada’s forests experiencing warm anomalies of above 2 °C and unprecedented drought and wildfires, providing a unique case to examine the response of boreal forest net carbon uptake to climate extremes. Here we combine satellite-based atmospheric CO2 flux inversions with ground-based in situ observations of CO2 fluxes and concentrations to investigate Canada’s forest net carbon uptake and its underlying mechanisms in 2023. We find that, compared with 2015–2022, Canada’s forest net carbon uptake was enhanced by 0.28 ± 0.23 PgC, offsetting 38–48% of Canadian wildfire emissions in 2023. This enhanced net uptake was dominated by large ecosystem respiration reductions, mainly attributable to severe root-zone soil moisture deficits and the unimodal temperature response of respiration. However, most dynamic global vegetation models failed to simulate the respiration reductions and the responses to hydrothermal conditions well. This study improves our understanding of boreal forest net carbon uptake in response to climate extremes and highlights an urgent need to improve vegetation models under global warming.

UR - https://www.scopus.com/pages/publications/105026696726

U2 - 10.1038/s41561-025-01875-1

DO - 10.1038/s41561-025-01875-1

M3 - Article

AN - SCOPUS:105026696726

SN - 1752-0894

VL - 19

SP - 145

EP - 152

JO - Nature Geoscience

JF - Nature Geoscience

IS - 2

ER -

Canadian net forest CO₂ uptake enhanced by heat drought via reduced respiration

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