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Monitoring and quantifying the impact of forest degradation associated to charcoal production in sub Saharan Africa through the integration of medium, high and very high-resolution remote sensing data and field-based information
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  • Fernando Sedano,
  • Natasha Ribeiro,
  • Almeida Sitoe,
  • Compton Tucker,
  • Ritvik Sahajpal,
  • Laura Duncanson,
  • Sa Lisboa
Fernando Sedano
University of Maryland

Corresponding Author:fsedano@umd.edu

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Natasha Ribeiro
Eduardo Mondlane University
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Almeida Sitoe
Eduardo Mondlane University
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Compton Tucker
NASA Goddard Space Flight Cen.
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Ritvik Sahajpal
University of Maryland
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Laura Duncanson
University of Maryland
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Sa Lisboa
Eduardo Mondlane University
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Abstract

Urban population in sub Saharan Africa (SSA) is rapidly growing. While only 30% of its population lived in urban centers in 2000, this figure will reach 60% by year 2050. Urban energy demand is closely tied to forest degradation. Charcoal is the main source of cooking fuel for eighty percent of African urban households and its overall consumption is expected to rise by 2040. Charcoal production is already the main driver of forest degradation in SSA. REDD+ guidelines encourage countries to identify and describe individual activities and drivers causing forest degradation as an initial step to define suitable methods for measuring and monitoring and formulate appropriate strategies and policies. Yet, forest degradation associated to charcoal production remains largely under reported. Charcoal production results in partial removals of forest cover that do not necessarily involve significant variations of the spectral signal. As a consequence, efforts to monitor forest degradation associated to charcoal production with medium resolution data has proved elusive. We present initial results of our effort to monitor and quantify carbon emissions from forest degradation due to charcoal production in SSA. Our work combines time series of multi sensor medium (20 – 30m), high (2m) and very high (0.5m) spatial resolution sensors with field data to characterize the spatial and temporal dynamics of charcoal production in charcoal production sites across SSA. The integration of these datasets provides the means to map, monitor and measure charcoal kilns, and subsequently quantify the magnitude and intensity of aboveground biomass removals associated to charcoal production at a level of detail and precision not reported previously. Our initial results reveal that charcoal production accounts for a larger share of greenhouse gas emission than previously reported, highlight its negative impacts on the ecosystem, and question the long-term sustainability of charcoal production under current and future urban energy demands. This work is a first step towards the development of a monitoring, reporting and verification system specific to forest degradation in the SSA context.