Variation in black carbon concentration and aerosol optical properties in Beijing: Role of emission control and meteorological transport variability

Black carbon (BC), which is a by-product with incomplete combustion of carbonaceous materials, can be used as an indicator of combustion emissions and is an important climate forcer. In this study, a spatial–temporal synthesis of BC aerosols and the affecting factors was conducted in urban Beijing....

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Bibliographic Details
Published in:Chemosphere (Oxford) 2020-09, Vol.254, p.126849-126849, Article 126849
Main Authors: Xia, Yunjie, Wu, Yunfei, Huang, Ru-Jin, Xia, Xiangao, Tang, Jie, Wang, Mian, Li, Jiwei, Wang, Chaoying, Zhou, Chang, Zhang, Renjian
Format: Article
Language:English
Subjects:
Beijing
Black carbon
Emission control
Transport variability
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Summary:Black carbon (BC), which is a by-product with incomplete combustion of carbonaceous materials, can be used as an indicator of combustion emissions and is an important climate forcer. In this study, a spatial–temporal synthesis of BC aerosols and the affecting factors was conducted in urban Beijing. As observed, BC showed a spatial pattern with high concentration in south and low in north. BC concentration evidently decreased by approximately 61% between 2005 and 2017. From 2015 to 2017, the mass ratio of BC/PM2.5 dropped by 28%, which suggested a more efficient effect of control measures to BC than PM2.5. The BC/CO ratio dropped by 22%, which indicated the decreasing emission from fossil fuel sources. With regard to BC loading, the spectral dependence of absorption aerosol exhibited significant seasonal variations. High absorption Ångström exponent (α) was observed during heating season, which reflected the increasing contribution of brown carbon (BrC) to light absorption. Backward trajectory analysis showed that the levels of BC and PM2.5 were high in Cluster-South and Cluster-West. BrC absorption was high in Cluster-West, Cluster-Northwest and Cluster-Northeast, due to the biomass and coal burning for domestic heating and aging processes on a regional scale. The effects of emission control and transport variability on pollutant variation were estimated on the basis of the cluster analysis. Results indicated that the effect of emission reduction was the major reason for the decrease of BC from 2015 to 2017, which resulted in a 34% reduction of BC concentration. Meanwhile, transport variability caused a 15% reduction. •A decrease by 61% in BC concentration was observed in urban Beijing during 2005–2017.•Approximately 34% of the decrease in BC concentration was attributed to emission control.•BrC contributed a considerable part of total aerosol light absorption, particularly during heating season.
ISSN:0045-6535
1879-1298
DOI:10.1016/j.chemosphere.2020.126849