Dynamic carbon allocation trade‐off: A robust approach to model tree biomass allometry
Type de ressource
Auteurs/contributeurs
- Yang, Mingxia (Auteur)
- Zhou, Xiaolu (Auteur)
- Liu, Zelin (Auteur)
- Li, Peng (Auteur)
- Liu, Caixia (Auteur)
- Huang, Huabing (Auteur)
- Tang, Jiayi (Auteur)
- Zhang, Cicheng (Auteur)
- Zou, Ziying (Auteur)
- Xie, Binggeng (Auteur)
- Peng, Changhui (Auteur)
Titre
Dynamic carbon allocation trade‐off: A robust approach to model tree biomass allometry
Résumé
Abstract
Forest above‐ground biomass (AGB) is often estimated by converting the observed tree size using allometric scaling between the dry weight and size of an organism. However, the variations in biomass allocation and scaling between tree crowns and stems due to survival competition during a tree's lifecycle remain unclear. This knowledge gap can improve the understanding of modelling tree biomass allometry because traditional allometries ignore the dynamics of allocation.
Herein, we characterised allometric scaling using the dynamic ratio (
r
) of the stem biomass (SB) to AGB and a dynamic exponent. The allometric models were biologically parameterised by the
r
values for initial, intermediate and final ages rather than only a regression result. The scaling was tested using field measurements of 421 species and 2213 different‐sized trees in pantropical regions worldwide.
We found that the scaling fluctuated with tree size, and this fluctuation was driven by the trade‐off relationship of biomass allocation between the tree crown and stem depending on the dynamic crown trait. The allometric scaling between SB and AGB varied from 0.8 to 1.0 for a tree during its entire lifecycle. The fluctuations presented a general law for the allometric scaling of the pantropical tree biomass and size. Our model quantified the trade‐off and explained 94.1% of the allometric relationship between the SB and AGB (93.8% of which between
D
2
H
and AGB) for pantropical forests, which resulted in a better fit than that of the traditional model. Considering the effects of the trade‐off on modelling, the actual biomass of large trees could be substantially greater than conventional estimates.
These results highlight the importance of coupling growth mechanisms in modelling allometry and provide a theoretical foundation for better describing and predicting forest carbon accumulation.
Publication
Methods in Ecology and Evolution
Volume
15
Numéro
5
Pages
886-899
Date
05/2024
Abrév. de revue
Methods Ecol Evol
Langue
en
ISSN
2041-210X, 2041-210X
Titre abrégé
Dynamic carbon allocation trade‐off
Consulté le
11/11/2024 21:05
Catalogue de bibl.
DOI.org (Crossref)
Référence
Yang, M., Zhou, X., Liu, Z., Li, P., Liu, C., Huang, H., Tang, J., Zhang, C., Zou, Z., Xie, B., & Peng, C. (2024). Dynamic carbon allocation trade‐off: A robust approach to model tree biomass allometry. Methods in Ecology and Evolution, 15(5), 886–899. https://doi.org/10.1111/2041-210X.14315
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