Abstract
Unmanned aerial vehicles (UAVs) can provide new ways to measure forests and supplement expensive or labor-intensive inventory methods. Forest carbon, a key uncertainty in the global carbon cycle and also important for carbon conservation programs, is typically monitored using manned aircraft or extensive forest plot networks to estimate aboveground carbon density (ACD). Manned aircraft are only cost-effective when applied to large areas (>100,000 ha), while plot networks are most effective for total C stock estimation across large areas, not for quantifying spatially-explicit variation. We sought to develop an effective method for frequent and accurate ACD estimation at intermediate scales (100–100,000 ha) that would be sensitive to small-scale disturbance. Using small UAVs, we collected imagery of 516 ha of lowland forest in the Peruvian Amazon. We then used a structure-from-motion (SFM) approach to create a 3D model of forest canopy. Comparing SFM- and airborne Light Detection and Ranging (LiDAR)-derived estimates of canopy height and ACD, we found that SFM estimates of top-of-canopy height (TCH) and ACD were highly correlated with previous LiDAR estimates (r = 0.86–0.93 and r = 0.73–0.94 for TCH and ACD, respectively, at 0.1–4 ha grain sizes), with r = 0.92 for ACD determination at the 1 ha scale, despite SFM and LiDAR measurements being separated by two years in a dynamic forest. SFM and LiDAR estimates of mean TCH and mean ACD were highly similar, differing by only 0.4% and 0.04%, respectively, within mature forest. The technique allows inexpensive, near-real-time monitoring of ACD for ecological studies, payment for ecosystem services (PES) ventures, such as reducing emissions from deforestation and forest degradation (REDD+), forestry enterprises, and governance.
Highlights
Deforestation currently accounts for 6%–17% of global carbon emissions [1], as well as having negative effects on biodiversity and ecosystem services [2,3,4,5]
Considerable effort has been focused on understanding forest carbon cycles, and on ways to alter it in order to generate revenue and sequester carbon
While conventional remote sensing estimates of forest carbon have greatly improved our understanding of carbon density and the emissions from deforestation and degradation, there remain cases where higher spatial or temporal resolution tools are needed
Summary
Deforestation currently accounts for 6%–17% of global carbon emissions [1], as well as having negative effects on biodiversity and ecosystem services [2,3,4,5]. Carbon conservation is an effort to reduce carbon emissions from deforestation and forest degradation, and to actively manage forests to increase carbon stocks and maintain ecosystem services and biodiversity. A major challenge to this effort, has revolved around uncertainty in estimating the spatial heterogeneity of forest carbon stocks and monitoring the responses of those stocks to natural disturbance and land-cover/land-use change (LCLUC) [6,7]. Reducing this uncertainty is critical to estimating future carbon emissions from. LCLUC and natural processes, as well as management for economic returns in reducing emissions from deforestation and forest degradation (REDD+) and sustainable forestry enterprises
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