GC41D-1113
Impacts of Landscape Context on Patterns of Wind Downfall Damage in a Fragmented Amazonian Landscape
Thursday, 17 December 2015
Poster Hall (Moscone South)
Naomi Schwartz1, Maria Uriarte2, Ruth S DeFries2, Victor H Gutierrez-Velez2, Katia Fernandes3 and Miguel Pinedo-Vasquez4, (1)Columbia University of New York, Palisades, NY, United States, (2)Columbia University, New York, NY, United States, (3)International Research Institute for Climate and Society, Columbia University, Palisades, NY, United States, (4)Columbia University, Earth Institute Center for Environmental Sustainability, New York, NY, United States
Abstract:
Wind is a major disturbance in the Amazon and has both short-term impacts and lasting legacies in tropical forests. Observed patterns of damage across landscapes result from differences in wind exposure and stand characteristics, such as tree stature, species traits, successional age, and fragmentation. Wind disturbance has important consequences for biomass dynamics in Amazonian forests, and understanding the spatial distribution and size of impacts is necessary to quantify the effects on carbon dynamics. In November 2013, a mesoscale convective system was observed over the study area in Ucayali, Peru, a highly human modified and fragmented forest landscape. We mapped downfall damage associated with the storm in order to ask: how does the severity of damage vary within forest patches, and across forest patches of different sizes and successional ages? We applied spectral mixture analysis to Landsat images from 2013 and 2014 to calculate the change in non-photosynthetic vegetation fraction after the storm, and combined it with C-band SAR data from the Sentinel-1 satellite to predict downfall damage measured in 30 field plots using random forest regression. We then applied this model to map damage in forests across the study area. Using a land cover classification developed in a previous study, we mapped secondary and mature forest, and compared the severity of damage in the two. We found that damage was on average higher in secondary forests, but patterns varied spatially. This study demonstrates the utility of using multiple sources of satellite data for mapping wind disturbance, and adds to our understanding of the sources of variation in wind-related damage. Ultimately, an improved ability to map wind impacts and a better understanding of their spatial patterns can contribute to better quantification of carbon dynamics in Amazonian landscapes.