Variability of depolarization of aerosol particles in the megacity of Beijing: implications for the interaction between anthropogenic pollutants and mineral dust particles

• Published in: Atmospheric chemistry and physics Vol. 18; no. 24; pp. 18203 - 18217
• Main Authors: Tian, Yu, Pan, Xiaole, Nishizawa, Tomoaki, Kobayashi, Hiroshi, Uno, Itsushi, Wang, Xiquan, Shimizu, Atsushi, Wang, Zifa
• Format: Journal Article
• Language: English
• Published: Katlenburg-Lindau Copernicus GmbH 21.12.2018; Copernicus Publications
• Subjects: Aerosol particles; Aerosols; Air pollution; Air pollution measurements; Air quality; Analysis; Anthropogenic factors; Atmospheric particulates; Depolarization; Detection; Dust; Dust particles; Dust storms; Environmental aspects; Environmental health; Forecasts and trends; High humidity; Human influences; Megacities; Mixing; Mixing processes; Particle counters; Particulate matter; Pollutants; Pollution; Public health; Radiation counters; Relative humidity; Remote sensing; Remote sensing techniques; Sensing techniques; Spring; Summer; Urban areas; Water absorption; Water pollution; Winter; China; Beijing China
• ISSN: 1680-7324; 1680-7316; 1680-7324
• DOI: 10.5194/acp-18-18203-2018

East Asia is suffering from severe air pollution problems due to intensive anthropogenic emissions and natural mineral dust aerosols. During transport, the aerosol particles undergo complex mixing processes, resulting in great impacts on regional air quality, human health and climate. In this study, we conducted a long-term observation using an optical particle counter equipped with a polarization detection module (POPC) at an urban site in Beijing. Mass concentrations of both PM2.5 and PM10 estimated from POPC compared well with ground-based measurements. The results revealed that the observed depolarization ratio (δ, termed as the ratio of the intensity of the s-polarized signal to the intensity of the 120∘ backward scattering signal [s/(s+p)]) for aerosol particles in the fine mode was generally much lower in summer than that in spring as a result of predominance of different aerosol types. Mineral dust particles in the coarse mode normally had a large δ value (0.3±0.05) owing to their nonspherical shape; however, particles in the fine mode mostly had water-soluble compositions, which led to an apparent decrease of their δ values in particular high relative humidity (RH) conditions. Because the observation site was subject to the impact of frequent dust events in spring, the δ value of particle at 1 µm was almost twice as high as that (0.07±0.01) in summer. Based on size-resolved δ values, anthropogenic pollutants, mineral dust and polluted mineral dust particles and their contribution to local air quality could be well distinguished. About 26.7 % of substandard days (daily averaged PM2.5 concentration larger than 75 µg m−3) in Beijing featured high atmospheric loading of coarse-mode particles in winter and springtime. In particular, during severe pollution episodes in winter, the δ values of coarse-mode particles decreased by 13 %, which implies a high possibility of dust-related heterogeneous processes in pollution formation. During dust events, δ values of particles with optical size (Dp) of 5 µm evidently decreased, with an increase of the PM2.5 ∕ PM10 ratio as well as RH, indicating the morphological changes of mineral dust. This study confirmed that high RH tends to promote water absorption processes on the dust surface as well as the coating of soluble compounds, and suggested that remote sensing techniques for aerosols may underestimate the impact of dust particles due to the complex mixing of dust and anthropogenic particles in urban areas, and the interaction between dust particles and pollutants should be considered well by the optical model.