Abstract
Many post-fire on-site factors, including fire severity, management strategies, topography, and local climate, are concerns for forest managers and recovery ecologists to formulate forest vegetation recovery plans in response to climate change. We used the Vegetation Change Tracker (VCT) algorithm to map forest disturbance in the Daxing’anling area, Northeastern China, from 1987 to 2016. A support vector machine (SVM) classifier and historical fire records were used to separate burned patches from disturbance patches obtained from VCT. Afterward, stepwise multiple linear regression (SMLR), SVM, and random forest (RF) were applied to assess the statistical relationships between vegetation recovery characteristics and various influential factors. The results indicated that the forest disturbance events obtained from VCT had high spatial accuracy, ranging from 70% to 86% for most years. The overall accuracy of the annual fire patches extracted from the proposed VCT-SVM algorithm was over 92%. The modeling accuracy of post-fire vegetation recovery was excellent, and the validation results confirmed that the RF algorithm provided better prediction accuracy than SVM and SMLR. In conclusion, topographic variables (e.g., elevation) and meteorological variables (e.g., the post-fire annual precipitation in the second year, the post-fire average relative humidity in the fifth year, and the post-fire extreme maximum temperature in the third year) jointly affect vegetation recovery in this cold temperate continental monsoon climate region.
Highlights
The objectives of this study are to (a) validate the performance of the Vegetation Change Tracker (VCT)-support vector machine (SVM) algorithm for extracting burned areas in a cold temperate forest ecosystem and (b) to identify the factors contributing to vegetation recovery in a cold temperate forest ecosystem after disturbance and provide information for forest management in similar regions
We focused on fire disturbances that occurred in the Daxing’anling area
It was observed that forest disturbances frequently occurred during the study period, and no disturbance was observed in seven, six, and four years in the study period in the eastern, middle, and western quadrat, respectively
Summary
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations. Fire is a natural disturbance in ecosystems and promotes diversity and natural regeneration [1]. Warm and dry conditions increase wildfire activity [2]. Fire is a critical factor affecting atmospheric chemistry [3], forest ecosystems succession and health [4], carbon budgets, and land use transformation [5]. Fire affects the socioeconomic system, soil erosion, and the hydrological cycle [6]
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