Abstract
Long-term monitoring of vegetation is critical for understanding the dynamics of forest ecosystems, especially in Southeast Asia’s tropical forests, which play a significant role in the global carbon cycle and have continually been converted into various stages of secondary forests. In Thailand, long-term monitoring of forest dynamics during the successional process is limited to plot scales assuming from the distinct structure of successional stages. Our study highlights the potential of coupling airborne light detection and ranging (LiDAR) technology and stand age data derived from Landsat time-series to track back forest succession, and infer patterns in the plant area index (PAI) recovery. Here, using LIDAR data, we estimated the PAI of the 510 sample plots of a seasonal evergreen forest dispersed over the study area in Khao Yai National Park, Thailand, capturing a successional gradient of tropical secondary forests. The sample plots age was derived from the available Landsat time-series dataset (1972–2017). We developed a PAI recovery model during the first 42 years of the succession process. We investigated the relationship between the model residuals and PAI values with topographic factors, such as elevation, slope, and topographic wetness index. The results show that the PAI increased non-linearly (pseudo-R2 of 0.56) during the first 42 years of forest succession, and all three topographic factors have less influence on PAI variability. These results provide valuable information of the spatio-temporal PAI patterns during the successional process and help understand the dynamics of tropical secondary forests in Khao Yai National Park, Thailand. Such information is essential for forest management and local, regional, and global PAI synthesis. Moreover, our results provide significant information for ground-based spatial sampling strategies to enable more accurate PAI measurements.
Highlights
Among the world’s tropical forests, Southeast Asia’s tropical forests are considered to contribute significantly to carbon storage and climate mitigation, but they belong to the major deforestation areas [1,2]
This study demonstrated the combined use of light detection and ranging (LiDAR) data and stand age data derived from Landsat time-series to determine plant area index (PAI) patterns in a forest succession in Khao Yai National Park, Thailand
Effects of the topographic factors on PAI values and residuals are less significant or weak in our study. These findings provide an information of the long-term PAI recovery patterns during successional processes and the spatial variation in the PAI in heterogeneous tropical moist forests following disturbance
Summary
Among the world’s tropical forests, Southeast Asia’s tropical forests are considered to contribute significantly to carbon storage and climate mitigation, but they belong to the major deforestation areas [1,2]. After deforestation, these forests feature patches of deforested areas and various stages of recovered forest through succession [3,4], where each stage has different forest structural attributes, species diversity, species composition, and capability in the forest ecosystem [3,5]. Long-term LAI monitoring following stand regrowth would further enhance our understanding of the dynamic changes in tropical forests and the climate impacts on tropical forest ecosystems
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