Global variation in the ratio of sapwood to leaf area explained by optimality principles

Huiying Xu; Han Wang; I. Colin Prentice; Sandy P. Harrison; Lucy Rowland; Maurizio Mencuccini; Pablo Sanchez-Martinez; Pengcheng He; Ian J. Wright; Stephen Sitch; Meng Li; Qing Ye

doi:10.1111/nph.70916

Global variation in the ratio of sapwood to leaf area explained by optimality principles

Huiying Xu, Han Wang^*, I. Colin Prentice, Sandy P. Harrison, Lucy Rowland, Maurizio Mencuccini, Pablo Sanchez-Martinez, Pengcheng He, Ian J. Wright, Stephen Sitch, Meng Li, Qing Ye

^*Corresponding author for this work

School of Natural Sciences

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

1 Citation (Scopus)

Abstract

• The sapwood area supporting a given leaf area (Huber value, v_H) reflects the coupling between carbon uptake and water transport and loss at a whole-plant level. Geographic variation in v_H presumably reflects plant strategic adaptations, but the lack of a general explanation for such variation hinders its representation in vegetation models and assessment of its impact on the global carbon and water cycles.

• Here we develop a simple hydraulic trait model to predict optimal v_H by matching stem water supply and leaf water loss, and test its performance against two extensive plant hydraulic datasets.

• We show that our eco-evolutionary optimality-based model explains nearly 60% of global v_H variation in response to light, vapour pressure deficit, temperature and sapwood conductivity. Enhanced hydraulic efficiency with warmer temperatures reduces the sapwood area required to support a given leaf area, whereas high irradiance (supporting increased photosynthetic capacity) and drier air increase it.

• This study thus provides a route to modelling variation in functional traits through the coordination of carbon uptake and water transport processes.

Original language	English
Number of pages	13
Journal	New Phytologist
Early online date	28 Jan 2026
DOIs	https://doi.org/10.1111/nph.70916
Publication status	E-pub ahead of print - 28 Jan 2026

Bibliographical note

Publisher Copyright:
© 2026 The Author(s). New Phytologist © 2026 New Phytologist Foundation.

Keywords

carbon allocation
optimality
photosynthesis
plant functional traits
plant hydraulics

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10.1111/nph.70916

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title = "Global variation in the ratio of sapwood to leaf area explained by optimality principles",

abstract = "• The sapwood area supporting a given leaf area (Huber value, vH) reflects the coupling between carbon uptake and water transport and loss at a whole-plant level. Geographic variation in vH presumably reflects plant strategic adaptations, but the lack of a general explanation for such variation hinders its representation in vegetation models and assessment of its impact on the global carbon and water cycles. • Here we develop a simple hydraulic trait model to predict optimal vH by matching stem water supply and leaf water loss, and test its performance against two extensive plant hydraulic datasets. • We show that our eco-evolutionary optimality-based model explains nearly 60\% of global vH variation in response to light, vapour pressure deficit, temperature and sapwood conductivity. Enhanced hydraulic efficiency with warmer temperatures reduces the sapwood area required to support a given leaf area, whereas high irradiance (supporting increased photosynthetic capacity) and drier air increase it. • This study thus provides a route to modelling variation in functional traits through the coordination of carbon uptake and water transport processes.",

keywords = "carbon allocation, optimality, photosynthesis, plant functional traits, plant hydraulics",

author = "Huiying Xu and Han Wang and Prentice, \{I. Colin\} and Harrison, \{Sandy P.\} and Lucy Rowland and Maurizio Mencuccini and Pablo Sanchez-Martinez and Pengcheng He and Wright, \{Ian J.\} and Stephen Sitch and Meng Li and Qing Ye",

note = "Publisher Copyright: {\textcopyright} 2026 The Author(s). New Phytologist {\textcopyright} 2026 New Phytologist Foundation.",

year = "2026",

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day = "28",

doi = "10.1111/nph.70916",

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AU - Xu, Huiying

AU - Wang, Han

AU - Prentice, I. Colin

AU - Harrison, Sandy P.

AU - Rowland, Lucy

AU - Mencuccini, Maurizio

AU - Sanchez-Martinez, Pablo

AU - He, Pengcheng

AU - Wright, Ian J.

AU - Sitch, Stephen

AU - Li, Meng

AU - Ye, Qing

PY - 2026/1/28

Y1 - 2026/1/28

N2 - • The sapwood area supporting a given leaf area (Huber value, vH) reflects the coupling between carbon uptake and water transport and loss at a whole-plant level. Geographic variation in vH presumably reflects plant strategic adaptations, but the lack of a general explanation for such variation hinders its representation in vegetation models and assessment of its impact on the global carbon and water cycles. • Here we develop a simple hydraulic trait model to predict optimal vH by matching stem water supply and leaf water loss, and test its performance against two extensive plant hydraulic datasets. • We show that our eco-evolutionary optimality-based model explains nearly 60% of global vH variation in response to light, vapour pressure deficit, temperature and sapwood conductivity. Enhanced hydraulic efficiency with warmer temperatures reduces the sapwood area required to support a given leaf area, whereas high irradiance (supporting increased photosynthetic capacity) and drier air increase it. • This study thus provides a route to modelling variation in functional traits through the coordination of carbon uptake and water transport processes.

AB - • The sapwood area supporting a given leaf area (Huber value, vH) reflects the coupling between carbon uptake and water transport and loss at a whole-plant level. Geographic variation in vH presumably reflects plant strategic adaptations, but the lack of a general explanation for such variation hinders its representation in vegetation models and assessment of its impact on the global carbon and water cycles. • Here we develop a simple hydraulic trait model to predict optimal vH by matching stem water supply and leaf water loss, and test its performance against two extensive plant hydraulic datasets. • We show that our eco-evolutionary optimality-based model explains nearly 60% of global vH variation in response to light, vapour pressure deficit, temperature and sapwood conductivity. Enhanced hydraulic efficiency with warmer temperatures reduces the sapwood area required to support a given leaf area, whereas high irradiance (supporting increased photosynthetic capacity) and drier air increase it. • This study thus provides a route to modelling variation in functional traits through the coordination of carbon uptake and water transport processes.

KW - carbon allocation

KW - optimality

KW - photosynthesis

KW - plant functional traits

KW - plant hydraulics

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DO - 10.1111/nph.70916

M3 - Article

C2 - 41603198

AN - SCOPUS:105029050511

SN - 0028-646X

JO - New Phytologist

JF - New Phytologist

ER -

Global variation in the ratio of sapwood to leaf area explained by optimality principles

Abstract

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Keywords

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