The vertical distribution of biomass burning pollution over tropical South America from aircraft in situ measurements during SAMBBA
Darbyshire, E; Morgan, WT; Allan, JD; et al.Liu, D; Flynn, MJ; Dorsey, JR; O'Shea, SJ; Lowe, D; Szpek, K; Marenco, F; Johnson, BT; Bauguitte, S; Haywood, JM; Brito, JF; Artaxo, P; Longo, KM; Coe, H
Date: 3 May 2019
Journal
Atmospheric Chemistry and Physics
Publisher
European Geosciences Union (EGU)
Publisher DOI
Abstract
We examine processes driving the vertical distribution of biomass burning pollution following an integrated analysis of over 200 pollutant and meteorological profiles measured in situ during the South AMerican Biomass Burning Analysis (SAMBBA) field experiment. This study will aid future work examining the impact of biomass burning on ...
We examine processes driving the vertical distribution of biomass burning pollution following an integrated analysis of over 200 pollutant and meteorological profiles measured in situ during the South AMerican Biomass Burning Analysis (SAMBBA) field experiment. This study will aid future work examining the impact of biomass burning on weather, climate and air quality.</p> During the dry season there were significant contrasts in the composition and vertical distribution of haze between western and eastern regions of tropical South America. Owing to an active or residual convective mixing layer, the aerosol abundance was similar from the surface to <span classCombining double low line"inline-formula">ĝ1/41.5</span> <span classCombining double low line"inline-formula">km</span> in the west and <span classCombining double low line"inline-formula">ĝ1/43</span> <span classCombining double low line"inline-formula">km</span> in the east. Black carbon mass loadings were double as much in the east (1.7 <span classCombining double low line"inline-formula">μg mĝ'3</span>) than the west (0.85 <span classCombining double low line"inline-formula">μg mĝ'3</span>), but aerosol scattering coefficients at 550 <span classCombining double low line"inline-formula">nm</span> were similar (<span classCombining double low line"inline-formula">ĝ1/4120</span> <span classCombining double low line"inline-formula">Mmĝ'1</span>), as too were CO near-surface concentrations (310-340 <span classCombining double low line"inline-formula">ppb</span>). We attribute these contrasts to the more flaming combustion of Cerrado fires in the east and more smouldering combustion of deforestation and pasture fires in the west. Horizontal wind shear was important in inhibiting mixed layer growth and plume rise, in addition to advecting pollutants from the Cerrado regions into the remote tropical forest of central Amazonia. Thin layers above the mixing layer indicate the roles of both plume injection and shallow moist convection in delivering pollution to the lower free troposphere. However, detrainment of large smoke plumes into the upper free troposphere was very infrequently observed. Our results reiterate that thermodynamics control the pollutant vertical distribution and thus point to the need for correct model representation so that the spatial distribution and vertical structure of biomass burning smoke is captured.</p> We observed an increase of aerosol abundance relative to CO with altitude both in the background haze and plume enhancement ratios. It is unlikely associated with thermodynamic partitioning, aerosol deposition or local non-fire sources. We speculate it may be linked to long-range transport from West Africa or fire combustion efficiency coupled to plume injection height. Further enquiry is required to explain the phenomenon and explore impacts on regional climate and air quality.
Mathematics and Statistics
Faculty of Environment, Science and Economy
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