Use este identificador para citar ou linkar para este item: https://repositorio.inpa.gov.br/handle/1/18826
Título: Tree allometry and improved estimation of carbon stocks and balance in tropical forests
Autor: Chave, Jérôme
Andalo, Christophe
Brown, Sandra L.
Cairns, Michael A.
Chambers, Jeffrey Quintin
Eamus, Derek
Fölster, Horst
Fromard, François
Higuchi, Niro
Kira, T.
Lescure, J. P.
Nelson, Bruce Walker
Ogawa, Husato
Puig, Henri
Riéra, Bernard
Yamakura, Takuo
Palavras-chave: Carbon
Allometry
Biomass
Carbon Balance
Tree
Tropical Forest
Biomass
Growth, Development And Aging
Humidity
Regression Analysis
Statistical Model
Theoretical Model
Tree
Tropic Climate
Biomass
Carbon
Humidity
Models, Statistical
Models, Theoretical
Regression Analysis
Trees
Tropical Climate
Data do documento: 2005
Revista: Oecologia
Encontra-se em: Volume 145, Número 1, Pags. 87-99
Abstract: Tropical forests hold large stores of carbon, yet uncertainty remains regarding their quantitative contribution to the global carbon cycle. One approach to quantifying carbon biomass stores consists in inferring changes from long-term forest inventory plots. Regression models are used to convert inventory data into an estimate of aboveground biomass (AGB). We provide a critical reassessment of the quality and the robustness of these models across tropical forest types, using a large dataset of 2,410 trees ≥ 5 cm diameter, directly harvested in 27 study sites across the tropics. Proportional relationships between aboveground biomass and the product of wood density, trunk cross-sectional area, and total height are constructed. We also develop a regression model involving wood density and stem diameter only. Our models were tested for secondary and old-growth forests, for dry, moist and wet forests, for lowland and montane forests, and for mangrove forests. The most important predictors of AGB of a tree were, in decreasing order of importance, its trunk diameter, wood specific gravity, total height, and forest type (dry, moist, or wet). Overestimates prevailed, giving a bias of 0.5-6.5% when errors were averaged across all stands. Our regression models can be used reliably to predict aboveground tree biomass across a broad range of tropical forests. Because they are based on an unprecedented dataset, these models should improve the quality of tropical biomass estimates, and bring consensus about the contribution of the tropical forest biome and tropical deforestation to the global carbon cycle. © Springer-Verlag 2005.
DOI: 10.1007/s00442-005-0100-x
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