Abstract
Airborne lidar is a technology well-suited for mapping many forest attributes, including aboveground biomass (AGB) stocks and changes in selective logging in tropical forests. However, trade-offs still exist between lidar pulse density and accuracy of AGB estimates. We assessed the impacts of lidar pulse density on the estimation of AGB stocks and changes using airborne lidar and field plot data in a selectively logged tropical forest located near Paragominas, Para, Brazil. Field-derived AGB was computed at 85 square 50 × 50 m plots in 2014. Lidar data were acquired in 2012 and 2014, and for each dataset the pulse density was subsampled from its original density of 13.8 and 37.5 pulses·m−2 to lower densities of 12, 10, 8, 6, 4, 2, 0.8, 0.6, 0.4 and 0.2 pulses·m−2. For each pulse density dataset, a power-law model was developed to estimate AGB stocks from lidar-derived mean height and corresponding changes between the years 2012 and 2014. We found that AGB change estimates at the plot level were only slightly affected by pulse density. However, at the landscape level we observed differences in estimated AGB change of >20 Mg·ha−1 when pulse density decreased from 12 to 0.2 pulses·m−2. The effects of pulse density were more pronounced in areas of steep slope, especially when the digital terrain models (DTMs) used in the lidar derived forest height were created from reduced pulse density data. In particular, when the DTM from high pulse density in 2014 was used to derive the forest height from both years, the effects on forest height and the estimated AGB stock and changes did not exceed 20 Mg·ha−1. The results suggest that AGB change can be monitored in selective logging in tropical forests with reasonable accuracy and low cost with low pulse density lidar surveys if a baseline high-quality DTM is available from at least one lidar survey. We recommend the results of this study to be considered in developing projects and national level MRV systems for REDD+ emission reduction programs for tropical forests.
Highlights
The Amazon is the largest remaining tropical forest in the world, its original extent has been steadily reduced due to deforestation and forest degradation, deforestation rates in Brazil have decreased by 70% since 2004 [1,2]
We evaluated the impacts of airborne lidar pulse density on aboveground biomass (AGB) stocks and AGB change estimation in a selectively logged Amazon tropical forest
We confirmed that HMEAN is a stable lidar-derived metric for estimating AGB stock in selective logging
Summary
The Amazon is the largest remaining tropical forest in the world, its original extent has been steadily reduced due to deforestation and forest degradation, deforestation rates in Brazil have decreased by 70% since 2004 [1,2]. Selective logging of valuable tree species has been an important land use of tropical forest in the Brazilian Amazon [3,4]. Selective logging has continued apace with degradation from forest fires and forest fragmentation, and may degrade the Amazon forest through long term changes in structure, loss of forest carbon and species diversity [6]. Characterizing the spatial distribution of forest structure, aboveground biomass (AGB), and AGB changes are important prerequisites for understanding carbon cycle dynamics and for monitoring the impact of selective logging in tropical forests over time [7]. Landscape-wide estimates of AGB stocks and changes from selective logging in tropical forest are desired for ongoing climate mitigation efforts to Reduce Emissions from Deforestation and Forest Degradation (REDD+) and for Measuring, Report and Verification (MRV) systems [7,8]
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