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Can leaf area index and biomass be estimated from B raun‐ B lanquet cover scores in tropical forests?
Author(s) -
Döbert Timm F.,
Webber Bruce L.,
Sugau John B.,
Dickinson Katharine J.M.,
Didham Raphael K.
Publication year - 2015
Publication title -
journal of vegetation science
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.1
H-Index - 115
eISSN - 1654-1103
pISSN - 1100-9233
DOI - 10.1111/jvs.12310
Subject(s) - leaf area index , understory , biomass (ecology) , environmental science , vegetation (pathology) , plant cover , plant community , ecology , forestry , canopy , geography , agroforestry , physical geography , agronomy , species richness , biology , medicine , pathology
Questions The loss and degradation of tropical forests is having severe impacts on the dynamics of understorey plant communities. Understanding these impacts requires efficient ways to measure vegetation change over broad spatial and temporal scales. Leaf area index ( LAI ) and above‐ground biomass are preferred quantitative measures of variation in plant community structure. However, their accurate measurement requires destructive sampling, which can be impractical or inappropriate. Here we test whether semi‐quantitative assessment of Braun‐Blanquet vegetation cover scores is a reliable proxy for direct quantitative measures of LAI and above‐ground biomass of differing plant growth forms ( PGF ) within tropical forests. Location Six hundred square kilometre area of tropical lowland rain forest in Sabah, Malaysia. Methods We sampled understorey rain forest plant communities across a disturbance gradient in 2 × 2 m plots at 301 locations. We used a modified Braun‐Blanquet scale to estimate plant cover, destructively harvested all live above‐ground biomass up to a height of 2 m, calculated the above‐ground biomass of each species from separately processed stem and leaf fractions in each plot, and then calculated LAI using reference measures of specific leaf area for each species. For each of nine PGF s, we regressed LAI and biomass against the nine‐point Braun‐Blanquet ordinal transform scale ( OTS ) using linear mixed effects models. Results We found a simple, uniform logarithmic scaling of LAI with increasing Braun‐Blanquet cover classes that was consistent across most PGF s, and with slope estimates close to 1.0. By contrast, no simple scaling relationship was found for above‐ground biomass, with most PGF s exhibiting an asymptotic relationship in which the Braun‐Blanquet estimates across high cover scores provided almost no resolution of observed variation in empirical biomass measures. Conclusions We found that the Braun‐Blanquet OTS provides a remarkably simple and accurate logarithmic scaling of LAI , but care should be taken in applying scaling rules uniformly across PGF s. In contrast, the Braun‐Blanquet OTS shows a more complex relationship with plant above‐ground biomass and we caution against its unconditional use for biomass estimation. The findings of this study should be broadly applicable to other ecosystems due to the heterogeneity of plant communities included in this work.

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