Abstract
Abstract. We use the GLOMAP global aerosol model evaluated against observations of surface particulate matter (PM2.5) and aerosol optical depth (AOD) to better understand the impacts of biomass burning on tropical aerosol over the period 2003 to 2011. Previous studies report a large underestimation of AOD over regions impacted by tropical biomass burning, scaling particulate emissions from fire by up to a factor of 6 to enable the models to simulate observed AOD. To explore the uncertainty in emissions we use three satellite-derived fire emission datasets (GFED3, GFAS1 and FINN1). In these datasets the tropics account for 66–84 % of global particulate emissions from fire. With all emission datasets GLOMAP underestimates dry season PM2.5 concentrations in regions of high fire activity in South America and underestimates AOD over South America, Africa and Southeast Asia. When we assume an upper estimate of aerosol hygroscopicity, underestimation of AOD over tropical regions impacted by biomass burning is reduced relative to previous studies. Where coincident observations of surface PM2.5 and AOD are available we find a greater model underestimation of AOD than PM2.5, even when we assume an upper estimate of aerosol hygroscopicity. Increasing particulate emissions to improve simulation of AOD can therefore lead to overestimation of surface PM2.5 concentrations. We find that scaling FINN1 emissions by a factor of 1.5 prevents underestimation of AOD and surface PM2.5 in most tropical locations except Africa. GFAS1 requires emission scaling factor of 3.4 in most locations with the exception of equatorial Asia where a scaling factor of 1.5 is adequate. Scaling GFED3 emissions by a factor of 1.5 is sufficient in active deforestation regions of South America and equatorial Asia, but a larger scaling factor is required elsewhere. The model with GFED3 emissions poorly simulates observed seasonal variability in surface PM2.5 and AOD in regions where small fires dominate, providing independent evidence that GFED3 underestimates particulate emissions from small fires. Seasonal variability in both PM2.5 and AOD is better simulated by the model using FINN1 emissions. Detailed observations of aerosol properties over biomass burning regions are required to better constrain particulate emissions from fires.
Highlights
Open biomass burning is an important source of trace gases and particulate matter (PM) to the atmosphere (Crutzen and Andreae, 1990; Andreae and Merlet, 2001; Van der Werf et al, 2010)
The overall bias between model and observations is smallest with Fire Inventory version 1.0 (FINN1) emissions (NMBF = −0.25) compared to Global Fire Emissions Database version 3 (GFED3) (NMBF = −0.49) or Global Fire Assimilation System version 1.0 (GFAS1) (NMBF = −0.62), with simulated monthly mean concentrations mostly within a factor of ∼ 2 of the observations
The correlation between model and observations across all sites is relatively similar between the three emission datasets, with a slightly stronger correlation with GFED3 emissions (r2 = 0.83) compared to FINN1 (r2 = 0.77) and GFAS1 (r2 = 0.79)
Summary
Open biomass burning is an important source of trace gases and particulate matter (PM) to the atmosphere (Crutzen and Andreae, 1990; Andreae and Merlet, 2001; Van der Werf et al, 2010). The influence of biomass burning aerosol on surface radiation can have subsequent impacts on the biosphere. Reddington et al.: Analysis of particulate emissions from tropical biomass burning radiation (Oliveira et al, 2007; Doughty et al, 2010), which has been shown to be a regionally important process over the Amazon (Rap et al, 2015). PM from biomass burning can substantially degrade regional air quality, leading to adverse effects on human health (Emmanuel, 2000; Frankenberg et al, 2005; Johnston et al, 2012; Jacobson et al, 2014; Reddington et al, 2015). A better understanding of particulate emissions is needed to improve predictions of the impacts of biomass burning on climate and air quality. We use a global aerosol model with tropical observations of surface PM and aerosol optical depth (AOD) to better understand the impact of tropical fires on atmospheric aerosol
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