Allometric Models for Predicting Aboveground Biomass in Two Widespread Woody Plants in Hawaii.
Authors:
Litton, Creighton M. Boone Kauffman, J. USDA, FS
Source:
Biotropica. 2008 May, v. 40, no. 3 Blackwell Publishing Inc, p. 313-320.
NALT Subjects:
allometry Dodonaea viscosa Metrosideros polymorpha nonlinear models prediction dry matter accumulation plant growth woody plants equations biomass tropical forests tree and stand measurements climatic factors regression analysis Hawaii
Other Subjects:
diameter at breast height generalized allometric models nonlinear regression Hawaii Volcanoes National Park
Issue Date:
May-2008
Abstract:
Allometric models are important for quantifying biomass and carbon storage in terrestrial ecosystems. Generalized allometry exists for tropical trees, but species- and site-specific models are more accurate. We developed species-specific models to predict aboveground biomass in two of the most ubiquitous natives in Hawaiian forests and shrublands, Metrosideros polymorpha and Dodonaea viscosa. The utility of the M. polymorpha allometry for predicting biomass across a range of sites was explored by comparing size structure (diameter at breast height vs. tree height) of the trees used to develop the models against trees from four M. polymorpha-dominated forests along a precipitation gradient (1630-2380 mm). We also compared individual tree biomass estimated with the M. polymorpha model against existing generalized equations, and the D. viscosa model with an existing species-specific model. Our models were highly significant and displayed minimal bias. Metrosideros polymorpha size structures from the three highest precipitation sites fell well within the 95% confidence intervals for the harvested trees, indicating that the models are applicable at these sites. However, size structure in the area with the lowest precipitation differed from those in the higher rainfall sites, emphasizing that care should be taken in applying the models too widely. Existing generalized allometry differed from the M. polymorpha model by up to 88 percent, particularly at the extremes of the data range examined, underestimating biomass in small trees and overestimating in large trees. The existing D. viscosa model underestimated biomass across all sizes by a mean of 43 percent compared to our model. The species-specific models presented here should enable more accurate estimates of biomass and carbon sequestration in Hawaiian forests and shrublands.
