Abstract
Tree and plant structures remaining after fires reflect well their degree of consumption, and are therefore good indicators of fire severity. Satellite optical images are commonly used to estimate fire severity. However, depending on the severity of a fire, these sensors have a limited ability to penetrate the canopy down to the ground. Airborne light detection and ranging (LiDAR) can overcome this limitation. Assessing the differences between areas that have been burned in different fire severities based on satellite images of plant and tree structures remaining after fires is important, given its widespread use to characterize fires and fire impacts (e.g., carbon emissions). Here, we measured the remaining tree structures after a fire in a forest stand burned in SE Spain in the summer of 2017. We used high-resolution LiDAR data, acquired from an unmanned aerial vehicle (UAV) six months after the fire. This information was crossed with fire severity levels based on the relativized burnt ratio (RBR) derived from Sentinel 2A images acquired a few months before and after fire. LiDAR tree structure data derived from vertical canopy profiles (VCPs) were classified into three clusters, using hierarchical principal component analysis (HPCA), followed by a random forest (RF) to select the most important variables in distinguishing the cluster groups. Among these, crown leaf area index (LAI), crown leaf area density (LAD), crown volume, tree height and tree height skewness, among others, were the most significant variables, and reflected well the degree of combustion undergone by the trees based on the response of these variables to variations in fire severity from RBR Sentinel 2A. LiDAR metrics were able to distinguish crown fire from surface fire through changes in the understory LAI and understory and midstory vegetation. The three tree structure clusters were well separated among each other and significantly related with the RBR Sentinel 2A-derived fire severity categories. Unburned and low-severity burned areas were more diverse in tree structures than moderate and high severity burned ones. The LiDAR metrics derived from VCPs demonstrated promising potential for characterizing fine-grained post-fire plant structures and fire damage when crossed with satellite-based fire severity metrics, turning into a promising approach for better characterizing fire impacts at a resolution needed for many ecological processes.
Highlights
Wildfires burn heterogeneously through forested landscapes; while some patches may have the trees barely scorched, others will have severe damage in their canopies, with all leaves and small branches fully burned
We made a comprehensive use of the vertical canopy profiles from high-density light detection and ranging (LiDAR) data to obtain several metrics related to biophysical single-tree characteristics, such as crown properties, leaf area index (LAI) values, vegetation layer distribution and diversity
Using inflection points to derive the canopy base height, crown volume could be estimated. All these metrics at the tree-level allowed the distinguishing of three clusters of tree morphologies, which were separated rather well among each other. These tree structure-derived clusters were unevenly distributed in the different relativized burnt ratio (RBR) Sentinel 2 fire severity levels
Summary
Wildfires burn heterogeneously through forested landscapes; while some patches may have the trees barely scorched, others will have severe damage in their canopies, with all leaves and small branches fully burned. The VCPs have been applied at the area-based scale to predict the time since fire (TSF) of the vegetation [51], to characterize vertical vegetation structures for a wide range of burned areas, using metrics derived from GLAS satellites (LiDAR full waveform pulses) [52], to characterize post-fire effects on the height and density of the vegetation [17], or to estimate the plot-level above-ground biomass (AGB) in burned plots [19]. The main novelties of this work are as follows: (i) the use of different approaches (i.e., voxels, height bins and original points) to estimate vertical crown profile metrics at the tree level; (ii) using LAD profiles and LAI values to estimate crown properties; (iii) using the breakpoints method to calculate the canopy base height (CBH) for deriving the crown volume, and (iv) using multitemporal passive optical multispectral imagery to relate spectral fire severity indices with LiDAR data
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