Artigo

Contrasting fire damage and fire susceptibility between seasonally flooded forest and upland forest in the Central Amazon using portable profiling LiDAR

Fire is an increasingly important agent of forest degradation in the Amazon, but little attention has been given to the susceptibility of seasonally flooded forests to fire. Satellite images suggest that forests flooded seasonally by nutrient-poor black waters are more susceptible to fire and may su...

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Autor principal: Almeida, Danilo Roberti Alves de
Outros Autores: Nelson, Bruce Walker, Schietti, Juliana, Görgens, Eric Bastos, Resende, Angélica Faria de, Stark, Scott C., Valbuena, Rubén
Grau: Artigo
Idioma: English
Publicado em: Remote Sensing of Environment 2020
Assuntos:
Deforestation
Fire Hazards
Floods
Incineration
Landforms
Optical Radar
Remote Sensing
Satellite Imagery
Amazon
Canopy Structure
Floodplain Forest
Forest Fires
Leaf Area
Structural Attributes
Terra Firme
Fires
Biomass-burning
Burning
Canopy
Floodplain Forest
Forest Fires
Leaf Area
Leaf Area Index
Lidar
Litter
Remote Sensing
Risk Assessment
Satellite Imagery
Seasonal Variation
Understory
Vegetation Structure
Amazonia
Acesso em linha: https://repositorio.inpa.gov.br/handle/1/17260
Resumo:
Fire is an increasingly important agent of forest degradation in the Amazon, but little attention has been given to the susceptibility of seasonally flooded forests to fire. Satellite images suggest that forests flooded seasonally by nutrient-poor black waters are more susceptible to fire and may suffer greater fire damage than nearby upland forests. Reasons for this difference may include the presence of a root mat, more fine fuel as litter and a drier understory in the flooded forest. We investigated this difference in the field, hypothesizing that differences in the aboveground structure of the pre-burn forest can contribute to the difference in impacts of, and susceptibility to, fires. We employed a portable profiling LiDAR (PPL), first to compare damage between adjacent black water seasonally flooded and upland forests that were burned by the same fire event, and to then assess pre-fire canopy structure attributes known to affect fire susceptibility. For both assessments, we used PPL-derived metrics of leaf area and vertical and horizontal variation in the structure of vegetation in the canopy. Four years after the fire, the LiDAR metrics showed greater combined effects of high damage and slow recovery in the seasonally flooded forest; reduction of total Leaf Area Index (LAI) after burning was only 10% for upland forest but was 71% in the flood forest. Compared to unburned upland, the canopy of unburned flood forest had structural differences that increase susceptibility to fire, including drier microclimate. It had more gaps, a more open understory and a lower upper canopy. Small patches lacking canopy closure (LAI < 1.0) were far more abundant in the unburned flood forest. We conclude that black water seasonally flooded forest suffers greater fire damage than upland forest and canopy structure contributes to its greater susceptibility to the occurrence of fires. This must be considered in assessments of future Amazon fire risks and impacts, including flood forest acting as a potential conduit for spreading fire to upland forest. © 2016

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