Detecting successional changes in tropical forest structure using GatorEye drone‐borne lidar
Almeida, Danilo Roberti Alves; Almeyda Zambrano, Angelica Maria; Broadbent, Eben North; Wendt, Amanda L.; Foster, Paul; Wilkinson, Benjamin E.; Salk, Carl; Papa, Daniel de Almeida; Stark, Scott Christopher; Valbuena, Ruben; Gorgens, Eric Bastos; Silva, Carlos Alberto; Brancalion, Pedro Henrique Santin; Fagan, Matthew; Meli, Paula; Chazdon, Robin
2020-11
Citation
Almeida, Danilo Roberti Alves; Almeyda Zambrano, Angelica Maria; Broadbent, Eben North; Wendt, Amanda L.; Foster, Paul; Wilkinson, Benjamin E.; Salk, Carl; Papa, Daniel de Almeida; Stark, Scott Christopher; Valbuena, Ruben; Gorgens, Eric Bastos; Silva, Carlos Alberto; Brancalion, Pedro Henrique Santin; Fagan, Matthew; Meli, Paula; Chazdon, Robin (2020). "Detecting successional changes in tropical forest structure using GatorEye drone‐borne lidar." Biotropica 52(6): 1155-1167.
Abstract
Drone‐based remote sensing is a promising new technology that combines the benefits of ground‐based and satellite‐derived forest monitoring by collecting fine‐scale data over relatively large areas in a cost‐effective manner. Here, we explore the potential of the GatorEye drone‐lidar system to monitor tropical forest succession by canopy structural attributes including canopy height, spatial heterogeneity, gap fraction, leaf area density (LAD) vertical distribution, canopy Shannon index (an index of LAD), leaf area index (LAI), and understory LAI. We focus on these variables’ relationship to aboveground biomass (AGB) stocks and species diversity. In the Caribbean lowlands of northeastern Costa Rica, we analyze nine tropical forests stands (seven second‐growth and two old‐growth). Stands were relatively homogenous in terms of canopy height and spatial heterogeneity, but not in their gap fraction. Neither species density nor tree community Shannon diversity index was significantly correlated with the canopy Shannon index. Canopy height, LAI, and AGB did not show a clear pattern as a function of forest age. However, gap fraction and spatial heterogeneity increased with forest age, whereas understory LAI decreased with forest age. Canopy height was strongly correlated with AGB. The heterogeneous mosaic created by successional forest patches across human‐managed tropical landscapes can now be better characterized. Drone‐lidar systems offer the opportunity to improve assessment of forest recovery and develop general mechanistic carbon sequestration models that can be rapidly deployed to specific sites, an essential step for monitoring progress within the UN Decade on Ecosystem Restoration.Potential of drone‐borne lidar to assess the structure and biomass of tropical forests at different successional stages. Forest age was positively correlated with spatial heterogeneity and gap fraction, and negatively with understory LAI. The heterogeneous mosaic created by successional forest patches across human‐managed tropical landscapes can now be better characterized.Publisher
CRC Press Wiley Periodicals, Inc.
ISSN
0006-3606 1744-7429
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