Size-resolved aerosol chemical analysis of extreme haze pollution events during early 2013 in urban Beijing, China

• Published in: Journal of hazardous materials Vol. 279; pp. 452 - 460
• Main Authors: Tian, Shili, Pan, Yuepeng, Liu, Zirui, Wen, Tianxue, Wang, Yuesi
• Format: Journal Article
• Language: English
• Published: Kidlington Elsevier B.V 30.08.2014; Elsevier
• Subjects: Aerosol chemistry; Aerosols; Aerosols - analysis; Air Pollutants - analysis; Air Pollution - analysis; Applied sciences; Atmospheric pollution; Carbon; Chemical analysis; China; Environmental Monitoring; Exact sciences and technology; Filtration; Haze; Haze pollution; Lead (metal); Mass closure; Metals, Heavy - chemistry; Particle Size; Particulate Matter - analysis; Pollution; Pollution abatement; Sampling; Size distributions; Urban Beijing; China; China, People's Rep., Beijing; Haze pollution; Urban Beijing; Mass closure; Aerosol chemistry; Size distributions; Organic matter; Chemical analysis; Haze; Samplings; Nitrates; Urban area; Ultrafine particle; Heavy metal; Submicron particle; Concentration measurement; Particle size distribution; Fine particle; Aerosols; Lead; Air pollution; Sampling; Solar radiation; Anthropogenic factor
• ISSN: 0304-3894; 1873-3336
• DOI: 10.1016/j.jhazmat.2014.07.023

•Anthropogenic species substantially accumulated in both fine and coarse particles.•Secondary organic carbon in PM1.1 decreased from clear to haze days.•The mass peak shifted to larger particles from clear to haze days.•The NO3−/SO42− ratio decreased with enhanced haze pollution.•Both mobile local and stationary regional sources were vital for haze formation. Using size-resolved filter sampling and chemical characterization, high concentrations of water-soluble ions, carbonaceous species and heavy metals were found in both fine (PM2.1) and coarse (PM2.1–9) particles in Beijing during haze events in early 2013. Even on clear days, average mass concentration of submicron particles (PM1.1) was several times higher than that previously measured in most of abroad urban areas. A high concentration of particulate matter on haze days weakens the incident solar radiation, which reduces the generation rate of secondary organic carbon in PM1.1. We show that the peak mass concentration of particles shifted from 0.43–0.65μm on clear days to 0.65–1.1μm on lightly polluted days and to 1.1–2.1μm on heavily polluted days. The peak shifts were also found for the following species: organic carbon, elemental carbon, NH4+, SO42−, NO3−, K, Cu, Zn, Cd and Pb. Our findings demonstrate that secondary inorganic aerosols (36%) and organic matter (26%) dominated the fine particle mass on heavily polluted days, while their contribution reduced to 29% and 18%, respectively, on clear days. Besides fine particles, anthropogenic chemical species also substantially accumulated in the coarse mode, which suggests that particles with aerodynamic diameter larger than 2.1μm cannot be neglected during severe haze events.