Closing a gap in tropical forest biomass estimation: taking crown mass variation into account in pantropical allometries

Closing a gap in tropical forest biomass estimation: taking crown mass variation into account in pantropical allometries

Accurately monitoring tropical forest carbon stocks is a challenge that remains outstanding. Allometric models that consider tree diameter, height and wood density as predictors are currently used in most tropical forest carbon studies. In particular, a pantropical biomass model has been widely used...

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Bibliographic Details
Published in:Biogeosciences Vol. 13; no. 5; pp. 1571 - 1585
Main Authors: Ploton, Pierre, Barbier, Nicolas, Takoudjou Momo, Stéphane, Réjou-Méchain, Maxime, Boyemba Bosela, Faustin, Chuyong, Georges, Dauby, Gilles, Droissart, Vincent, Fayolle, Adeline, Goodman, Rosa Calisto, Henry, Matieu, Kamdem, Narcisse Guy, Mukirania, John Katembo, Kenfack, David, Libalah, Moses, Ngomanda, Alfred, Rossi, Vivien, Sonké, Bonaventure, Texier, Nicolas, Thomas, Duncan, Zebaze, Donatien, Couteron, Pierre, Berger, Uta, Pélissier, Raphaël
Format: Journal Article Web Resource
Language:English
Published: Katlenburg-Lindau Copernicus GmbH 14-03-2016
European Geosciences Union
Copernicus Publications
Subjects:
Agriculture & agronomie
Agriculture & agronomy
allometric models
Allometry
Analysis
Bias
Biodiversity and Ecology
Biologie végétale (sciences végétales, sylviculture, mycologie...)
Biomass
Biomass energy
biomass estimation
Carbon
crown mass variation
Datasets
Environmental Sciences
Forest biomass
Forest carbon
Forest ecology
Forests
Life sciences
Mass
Phytobiology (plant sciences, forestry, mycology...)
Remote sensing
Sciences du vivant
Stocks
Systematic errors
Trees
Tropical climate
tropical forest
Tropical forests
Cameroon
Belgium
France
United States > US
tropical forest
biomass estimation
Tropics
allometrries
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Summary:Accurately monitoring tropical forest carbon stocks is a challenge that remains outstanding. Allometric models that consider tree diameter, height and wood density as predictors are currently used in most tropical forest carbon studies. In particular, a pantropical biomass model has been widely used for approximately a decade, and its most recent version will certainly constitute a reference model in the coming years. However, this reference model shows a systematic bias towards the largest trees. Because large trees are key drivers of forest carbon stocks and dynamics, understanding the origin and the consequences of this bias is of utmost concern. In this study, we compiled a unique tree mass data set of 673 trees destructively sampled in five tropical countries (101 trees > 100 cm in diameter) and an original data set of 130 forest plots (1 ha) from central Africa to quantify the prediction error of biomass allometric models at the individual and plot levels when explicitly taking crown mass variations into account or not doing so. We first showed that the proportion of crown to total tree aboveground biomass is highly variable among trees, ranging from 3 to 88 %. This proportion was constant on average for trees < 10 Mg (mean of 34 %) but, above this threshold, increased sharply with tree mass and exceeded 50 % on average for trees  ≥  45 Mg. This increase coincided with a progressive deviation between the pantropical biomass model estimations and actual tree mass. Taking a crown mass proxy into account in a newly developed model consistently removed the bias observed for large trees (> 1 Mg) and reduced the range of plot-level error (in %) from [−23; 16] to [0; 10]. The disproportionally higher allocation of large trees to crown mass may thus explain the bias observed recently in the reference pantropical model. This bias leads to far-from-negligible, but often overlooked, systematic errors at the plot level and may be easily corrected by taking a crown mass proxy for the largest trees in a stand into account, thus suggesting that the accuracy of forest carbon estimates can be significantly improved at a minimal cost.
Bibliography:scopus-id:2-s2.0-84960929947
ISSN:1726-4189
1726-4170
1726-4189
DOI:10.5194/bg-13-1571-2016