Species-specific biomass allometric models and expansion factors for indigenous and planted forests of the Mozambique highlands

Secondary Miombo woodlands and forest plantations occupy increasing areas in Mozambique, the former due to anthropogenic activities. Plantations, mainly species of Eucalyptus and Pinus , are being established on sites previously covered by secondary Miombo woodlands. This affects the evolution, cycl...

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Bibliographic Details
Published in:Journal of forestry research 2021-06, Vol.32 (3), p.1047-1065
Main Authors: Magalhães, Tarquinio Mateus, Cossa, Victoria Norberto, Guedes, Benard Soares, Fanheiro, Amélia Saraiva Monguela
Format: Article
Language:English
Subjects:
Analysis
Anthropogenic factors
Biomass
Biomedical and Life Sciences
Carbon dioxide
Carbon sequestration
Climate change
Climate models
Climate policy
Climatic changes
Environmental policy
Eucalyptus
Forest ecosystems
Forestry
Forests
Forests and forestry
Indigenous plants
Indigenous species
Introduced species
Life Sciences
Model testing
Original Paper
Plant species
Plantations
Planting density
Species
Stems
Variability
Woodlands
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Summary:Secondary Miombo woodlands and forest plantations occupy increasing areas in Mozambique, the former due to anthropogenic activities. Plantations, mainly species of Eucalyptus and Pinus , are being established on sites previously covered by secondary Miombo woodlands. This affects the evolution, cycle and spatiotemporal patterns of carbon (C) storage and stocks in forest ecosystems. The estimation of C storage, which is indispensable for formulating climate change policies on sequestrating CO 2 , requires tools such as biomass models and biomass conversion and expansion factors (BCEF). In Mozambique, these tools are needed for both indigenous forests and plantations. The objective of this study is to fit species-specific allometric biomass models and BCEF for exotic and indigenous tree species. To incorporate efficient inter-species variability, biomass equations were fitted using nonlinear mixed-effects models. All tree component biomass models had good predictability; however, better predictive accuracy and ability was observed for the 2-predictors biomass model with tree height as a second predictor. The majority of the variability in BCEF was explained by the variation in tree species. Miombo species had larger crown biomass per unit of stem diameter and stored larger amounts of biomass per stem volume. However, due to relatively rapid growth, larger stem diameters, heights, and stand density, the plantations stored more biomass per tree and per unit area.
ISSN:1007-662X
1993-0607
DOI:10.1007/s11676-020-01156-0