Warming of northern peatlands increases the global temperature overshoot challenge

Biqing Zhu; Chunjing Qiu; Thomas Gasser; Philippe Ciais; Robin D. Lamboll; Ashley Ballantyne; Jinfeng Chang; Nitin Chaudhary; Angela V. Gallego-Sala; Bertrand Guenet; Joseph Holden; Fortunat Joos; Thomas Kleinen; Min Jung Kwon; Irina Melnikova; Jurek Müller; Susan Page; Elodie Salmon; Carl Friedrich Schleussner; Guy Schurgers; Gaurav P. Shrivastav; Narasinha J. Shurpali; Katsumasa Tanaka; David Wårlind; Sebastian Westermann; Yi Xi; Wenxin Zhang; Yuan Zhang; Dan Zhu

doi:10.1016/j.oneear.2025.101353

Warming of northern peatlands increases the global temperature overshoot challenge

Biqing Zhu, Chunjing Qiu, Thomas Gasser, Philippe Ciais, Robin D. Lamboll, Ashley Ballantyne, Jinfeng Chang, Nitin Chaudhary, Angela V. Gallego-Sala, Bertrand Guenet, Joseph Holden, Fortunat Joos, Thomas Kleinen, Min Jung Kwon, Irina Melnikova, Jurek Müller, Susan Page, Elodie Salmon, Carl Friedrich Schleussner, Guy SchurgersGaurav P. Shrivastav, Narasinha J. Shurpali, Katsumasa Tanaka, David Wårlind, Sebastian Westermann, Yi Xi, Wenxin Zhang, Yuan Zhang, Dan Zhu

Ecosystem and Conservation Sciences

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

Abstract

Meeting the Paris Agreement's temperature goals requires limiting future carbon emissions, yet current policies make temporarily overshooting the 1.5°C target likely. The potential climate feedback from destabilizing peatlands, storing large amounts of carbon, remains poorly quantified. Using the reduced-complexity Earth System Model OSCAR with an integrated peat carbon module, we found that across various overshoot pathways that temporarily exceed 1.5°C–2.5°C, northern peatlands exhibit net positive feedback, amplifying the overshoot challenge. Warming increases peatlands’ net carbon uptake, but this is largely offset by higher methane emissions. We estimated that for each 1°C increase in peak warming, the positive feedback from peatlands decreases the remaining carbon budget by 37 GtCO₂ (22–48 GtCO₂). If the 1.5°C temperature target is exceeded, peatlands would increase carbon removal requirement by about 40 GtCO₂ (16–60 GtCO₂) (8.6%). Our findings highlight the importance of properly accounting for northern peatlands for estimating climate feedbacks, especially under overshoot scenarios.

Original language	English
Article number	101353
Journal	One Earth
Volume	8
Issue number	8
DOIs	https://doi.org/10.1016/j.oneear.2025.101353
State	Published - Aug 15 2025

Keywords

carbon
climate change
greenhouse gases
land surface model
northern peatlands
overshoot
reduced-complexity earth system model
temperature feedback

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.oneear.2025.101353

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Zhu, B., Qiu, C., Gasser, T., Ciais, P., Lamboll, R. D., Ballantyne, A., Chang, J., Chaudhary, N., Gallego-Sala, A. V., Guenet, B., Holden, J., Joos, F., Kleinen, T., Kwon, M. J., Melnikova, I., Müller, J., Page, S., Salmon, E., Schleussner, C. F., ... Zhu, D. (2025). Warming of northern peatlands increases the global temperature overshoot challenge. One Earth, 8(8), Article 101353. https://doi.org/10.1016/j.oneear.2025.101353

@article{6f66d1dea55c413abf35917195d28a7f,

title = "Warming of northern peatlands increases the global temperature overshoot challenge",

abstract = "Meeting the Paris Agreement's temperature goals requires limiting future carbon emissions, yet current policies make temporarily overshooting the 1.5°C target likely. The potential climate feedback from destabilizing peatlands, storing large amounts of carbon, remains poorly quantified. Using the reduced-complexity Earth System Model OSCAR with an integrated peat carbon module, we found that across various overshoot pathways that temporarily exceed 1.5°C–2.5°C, northern peatlands exhibit net positive feedback, amplifying the overshoot challenge. Warming increases peatlands{\textquoteright} net carbon uptake, but this is largely offset by higher methane emissions. We estimated that for each 1°C increase in peak warming, the positive feedback from peatlands decreases the remaining carbon budget by 37 GtCO2 (22–48 GtCO2). If the 1.5°C temperature target is exceeded, peatlands would increase carbon removal requirement by about 40 GtCO2 (16–60 GtCO2) (8.6\%). Our findings highlight the importance of properly accounting for northern peatlands for estimating climate feedbacks, especially under overshoot scenarios.",

keywords = "carbon, climate change, greenhouse gases, land surface model, northern peatlands, overshoot, reduced-complexity earth system model, temperature feedback",

author = "Biqing Zhu and Chunjing Qiu and Thomas Gasser and Philippe Ciais and Lamboll, \{Robin D.\} and Ashley Ballantyne and Jinfeng Chang and Nitin Chaudhary and Gallego-Sala, \{Angela V.\} and Bertrand Guenet and Joseph Holden and Fortunat Joos and Thomas Kleinen and Kwon, \{Min Jung\} and Irina Melnikova and Jurek M{\"u}ller and Susan Page and Elodie Salmon and Schleussner, \{Carl Friedrich\} and Guy Schurgers and Shrivastav, \{Gaurav P.\} and Shurpali, \{Narasinha J.\} and Katsumasa Tanaka and David W{\aa}rlind and Sebastian Westermann and Yi Xi and Wenxin Zhang and Yuan Zhang and Dan Zhu",

note = "Publisher Copyright: {\textcopyright} 2025 The Authors",

year = "2025",

month = aug,

day = "15",

doi = "10.1016/j.oneear.2025.101353",

language = "English",

volume = "8",

journal = "One Earth",

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Zhu, B, Qiu, C, Gasser, T, Ciais, P, Lamboll, RD, Ballantyne, A, Chang, J, Chaudhary, N, Gallego-Sala, AV, Guenet, B, Holden, J, Joos, F, Kleinen, T, Kwon, MJ, Melnikova, I, Müller, J, Page, S, Salmon, E, Schleussner, CF, Schurgers, G, Shrivastav, GP, Shurpali, NJ, Tanaka, K, Wårlind, D, Westermann, S, Xi, Y, Zhang, W, Zhang, Y & Zhu, D 2025, 'Warming of northern peatlands increases the global temperature overshoot challenge', One Earth, vol. 8, no. 8, 101353. https://doi.org/10.1016/j.oneear.2025.101353

TY - JOUR

T1 - Warming of northern peatlands increases the global temperature overshoot challenge

AU - Zhu, Biqing

AU - Qiu, Chunjing

AU - Gasser, Thomas

AU - Ciais, Philippe

AU - Lamboll, Robin D.

AU - Ballantyne, Ashley

AU - Chang, Jinfeng

AU - Chaudhary, Nitin

AU - Gallego-Sala, Angela V.

AU - Guenet, Bertrand

AU - Holden, Joseph

AU - Joos, Fortunat

AU - Kleinen, Thomas

AU - Kwon, Min Jung

AU - Melnikova, Irina

AU - Müller, Jurek

AU - Page, Susan

AU - Salmon, Elodie

AU - Schleussner, Carl Friedrich

AU - Schurgers, Guy

AU - Shrivastav, Gaurav P.

AU - Shurpali, Narasinha J.

AU - Tanaka, Katsumasa

AU - Wårlind, David

AU - Westermann, Sebastian

AU - Xi, Yi

AU - Zhang, Wenxin

AU - Zhang, Yuan

AU - Zhu, Dan

PY - 2025/8/15

Y1 - 2025/8/15

N2 - Meeting the Paris Agreement's temperature goals requires limiting future carbon emissions, yet current policies make temporarily overshooting the 1.5°C target likely. The potential climate feedback from destabilizing peatlands, storing large amounts of carbon, remains poorly quantified. Using the reduced-complexity Earth System Model OSCAR with an integrated peat carbon module, we found that across various overshoot pathways that temporarily exceed 1.5°C–2.5°C, northern peatlands exhibit net positive feedback, amplifying the overshoot challenge. Warming increases peatlands’ net carbon uptake, but this is largely offset by higher methane emissions. We estimated that for each 1°C increase in peak warming, the positive feedback from peatlands decreases the remaining carbon budget by 37 GtCO2 (22–48 GtCO2). If the 1.5°C temperature target is exceeded, peatlands would increase carbon removal requirement by about 40 GtCO2 (16–60 GtCO2) (8.6%). Our findings highlight the importance of properly accounting for northern peatlands for estimating climate feedbacks, especially under overshoot scenarios.

AB - Meeting the Paris Agreement's temperature goals requires limiting future carbon emissions, yet current policies make temporarily overshooting the 1.5°C target likely. The potential climate feedback from destabilizing peatlands, storing large amounts of carbon, remains poorly quantified. Using the reduced-complexity Earth System Model OSCAR with an integrated peat carbon module, we found that across various overshoot pathways that temporarily exceed 1.5°C–2.5°C, northern peatlands exhibit net positive feedback, amplifying the overshoot challenge. Warming increases peatlands’ net carbon uptake, but this is largely offset by higher methane emissions. We estimated that for each 1°C increase in peak warming, the positive feedback from peatlands decreases the remaining carbon budget by 37 GtCO2 (22–48 GtCO2). If the 1.5°C temperature target is exceeded, peatlands would increase carbon removal requirement by about 40 GtCO2 (16–60 GtCO2) (8.6%). Our findings highlight the importance of properly accounting for northern peatlands for estimating climate feedbacks, especially under overshoot scenarios.

KW - carbon

KW - climate change

KW - greenhouse gases

KW - land surface model

KW - northern peatlands

KW - overshoot

KW - reduced-complexity earth system model

KW - temperature feedback

UR - https://www.scopus.com/pages/publications/105009646126

U2 - 10.1016/j.oneear.2025.101353

DO - 10.1016/j.oneear.2025.101353

M3 - Article

AN - SCOPUS:105009646126

SN - 2590-3330

VL - 8

JO - One Earth

JF - One Earth

IS - 8

M1 - 101353

ER -

Warming of northern peatlands increases the global temperature overshoot challenge

Abstract

Keywords

UN SDGs

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