Thermal acclimation of stem respiration implies a weaker carbon-climate feedback

Han Zhang; Han Wang; Ian J Wright; I. Colin Prentice; Sandy P. Harrison; Nicholas G. Smith; Andrea Westerband; Lucy Rowland; Lenka Plavcová; Hugh Morris; Peter B Reich; Steven Jansen; Trevor Keenan; Ngoc  Nguyen

doi:10.1126/science.adr9978

Thermal acclimation of stem respiration implies a weaker carbon-climate feedback

Han Zhang, Han Wang, Ian J Wright, I. Colin Prentice, Sandy P. Harrison, Nicholas G. Smith, Andrea Westerband, Lucy Rowland, Lenka Plavcová, Hugh Morris, Peter B Reich, Steven Jansen, Trevor Keenan, Ngoc Nguyen

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

Abstract

The efflux of carbon dioxide (CO2) from woody stems, a proxy for stem respiration, is a critical carbon flux from ecosystems to the atmosphere, which increases with temperature on short timescales. However, plants acclimate their respiratory response to temperature on longer timescales, potentially weakening the carbon-climate feedback. The magnitude of this acclimation is uncertain despite its importance for predicting future climate change. We develop an optimality-based theory dynamically linking stem respiration with leaf water supply to predict its thermal acclimation. We show that the theory accurately reproduces observations of spatial and seasonal change. We estimate the global value for current annual stem CO2 efflux as 27.4 ± 5.9 PgC. By 2100, incorporating thermal acclimation reduces projected stem respiration without considering acclimation by 24 to 46%, thus reducing land ecosystem carbon emissions.

Original language	English
Pages (from-to)	984-988
Number of pages	5
Journal	Science
Volume	388
Issue number	6750
Early online date	29 May 2025
DOIs	https://doi.org/10.1126/science.adr9978
Publication status	First published - 29 May 2025

Keywords

Acclimatization
Carbon Cycle
Carbon Dioxide/metabolism
Carbon/metabolism
Cell Respiration
Climate Change
Ecosystem
Plant Leaves/metabolism
Plant Stems/metabolism
Seasons
Temperature
Water

UN SDGs

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

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10.1126/science.adr9978

supplementary Thermal_acclimation_of_stem_respirationAccepted author manuscript, 1.97 MBLicence: CC BY

Cite this

Zhang, H., Wang, H., Wright, I. J., Prentice, I. C., Harrison, S. P., Smith, N. G., Westerband, A., Rowland, L., Plavcová, L., Morris, H., Reich, P. B., Jansen, S., Keenan, T., & Nguyen, N. (2025). Thermal acclimation of stem respiration implies a weaker carbon-climate feedback. Science, 388(6750), 984-988. Advance online publication. https://doi.org/10.1126/science.adr9978

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title = "Thermal acclimation of stem respiration implies a weaker carbon-climate feedback",

abstract = "The efflux of carbon dioxide (CO2) from woody stems, a proxy for stem respiration, is a critical carbon flux from ecosystems to the atmosphere, which increases with temperature on short timescales. However, plants acclimate their respiratory response to temperature on longer timescales, potentially weakening the carbon-climate feedback. The magnitude of this acclimation is uncertain despite its importance for predicting future climate change. We develop an optimality-based theory dynamically linking stem respiration with leaf water supply to predict its thermal acclimation. We show that the theory accurately reproduces observations of spatial and seasonal change. We estimate the global value for current annual stem CO2 efflux as 27.4 ± 5.9 PgC. By 2100, incorporating thermal acclimation reduces projected stem respiration without considering acclimation by 24 to 46\%, thus reducing land ecosystem carbon emissions.",

keywords = "Acclimatization, Carbon Cycle, Carbon Dioxide/metabolism, Carbon/metabolism, Cell Respiration, Climate Change, Ecosystem, Plant Leaves/metabolism, Plant Stems/metabolism, Seasons, Temperature, Water",

author = "Han Zhang and Han Wang and Wright, \{Ian J\} and Prentice, \{I. Colin\} and Harrison, \{Sandy P.\} and Smith, \{Nicholas G.\} and Andrea Westerband and Lucy Rowland and Lenka Plavcov{\'a} and Hugh Morris and Reich, \{Peter B\} and Steven Jansen and Trevor Keenan and Ngoc Nguyen",

year = "2025",

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doi = "10.1126/science.adr9978",

language = "English",

volume = "388",

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AU - Zhang, Han

AU - Wang, Han

AU - Wright, Ian J

AU - Prentice, I. Colin

AU - Harrison, Sandy P.

AU - Smith, Nicholas G.

AU - Westerband, Andrea

AU - Rowland, Lucy

AU - Plavcová, Lenka

AU - Morris, Hugh

AU - Reich, Peter B

AU - Jansen, Steven

AU - Keenan, Trevor

AU - Nguyen, Ngoc

PY - 2025/5/29

Y1 - 2025/5/29

N2 - The efflux of carbon dioxide (CO2) from woody stems, a proxy for stem respiration, is a critical carbon flux from ecosystems to the atmosphere, which increases with temperature on short timescales. However, plants acclimate their respiratory response to temperature on longer timescales, potentially weakening the carbon-climate feedback. The magnitude of this acclimation is uncertain despite its importance for predicting future climate change. We develop an optimality-based theory dynamically linking stem respiration with leaf water supply to predict its thermal acclimation. We show that the theory accurately reproduces observations of spatial and seasonal change. We estimate the global value for current annual stem CO2 efflux as 27.4 ± 5.9 PgC. By 2100, incorporating thermal acclimation reduces projected stem respiration without considering acclimation by 24 to 46%, thus reducing land ecosystem carbon emissions.

AB - The efflux of carbon dioxide (CO2) from woody stems, a proxy for stem respiration, is a critical carbon flux from ecosystems to the atmosphere, which increases with temperature on short timescales. However, plants acclimate their respiratory response to temperature on longer timescales, potentially weakening the carbon-climate feedback. The magnitude of this acclimation is uncertain despite its importance for predicting future climate change. We develop an optimality-based theory dynamically linking stem respiration with leaf water supply to predict its thermal acclimation. We show that the theory accurately reproduces observations of spatial and seasonal change. We estimate the global value for current annual stem CO2 efflux as 27.4 ± 5.9 PgC. By 2100, incorporating thermal acclimation reduces projected stem respiration without considering acclimation by 24 to 46%, thus reducing land ecosystem carbon emissions.

KW - Acclimatization

KW - Carbon Cycle

KW - Carbon Dioxide/metabolism

KW - Carbon/metabolism

KW - Cell Respiration

KW - Climate Change

KW - Ecosystem

KW - Plant Leaves/metabolism

KW - Plant Stems/metabolism

KW - Seasons

KW - Temperature

KW - Water

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SP - 984

EP - 988

JO - Science

JF - Science

IS - 6750

ER -

Thermal acclimation of stem respiration implies a weaker carbon-climate feedback

Abstract

Keywords

UN SDGs

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