Abstract
Anthropogenic climate change is now considered to be one of the main factors causing an increase in both frequency and severity of wildfires. These fires are prone to release substantial quantities of CO2 in the atmosphere and to destroy natural ecosystems while reducing biodiversity. Depending on the ecosystem and climate regime, fires have distinct triggering factors and impacts. To better analyse and describe fire impact on different biomes, we investigated pre and post fire vegetation anomalies at global scale. The study was performed using several remotely sensed quantities ranging from optical vegetation indices (the enhanced vegetation index (EVI)) to vegetation opacities obtained at several microwave wavelengths (X-band, C-band, and L-band vegetation optical depth (X-VOD, C-VOD, and L-VOD)), ranging from 2 to 20 cm. It was found that C- and X-VOD are mostly sensitive to fire over low vegetation areas (grass and small bushes) or over tree leaves; while L-VOD depicts better the fire impact on tree trunks and branches. As a consequence, L-VOD is probably a better way of assessing fire impact on biomass. The study shows that L-VOD can be used to monitor fire affected areas as well as post-fire recovery, especially over densely vegetated areas.
Highlights
Wildfires are known to have several negative effects on soil and vegetation properties
The Mendocino Complex provoked a decrease in all vegetation variables (VVs), in L-Vegetation optical depth (VOD) (anom(L-VOD) = -0.08) and in enhanced vegetation index (EVI) (anom(EVI) = -0.10)
In forests, which generally maintain a steady humidity, we found that fires are linked with intense and prolonged drought
Summary
Wildfires are known to have several negative effects on soil and vegetation properties. They cause 25 deterioration of soil structure and porosity, removal of organic matter, loss of nutrients, ash entrapment, decreasing of microbial and soil-dwelling invertebrate communities, etc. By removing plant cover and inducing soil water repellency, wildfires can cause excess runoff which, in turn, can lead to floods and erosion (Moody and Martin, 2001; Shakesby and Doerr, 2005). Post-fire vegetation regeneration highly depends on the ecosystem and on the fire severity (Chu and Guo, 2013). Discussion started: 11 November 2021 c Author(s) 2021.
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