Impacts of aerosol compositions on visibility impairment in Xi'an, China

Daily particle light scattering coefficient, PM2.5 mass and chemical composition were measured in Xi’an from February to December 2009. Visibility was strongly affected by anthropogenic air pollution sources, resulting in an average visual range (VR) of 6.4 � 4.5 km. The threshold PM2.5 mass concentration, corresponding to VR <10 km, was w88 m gm � 3 . The revised IMPROVE equation was applied to estimate chemical extinction (bext), which on average was w15% lower than measured bext .P M2.5 ammonium sulfate was the largest contributor, accounting for w40% of bext, followed by organic matter (w24%), ammonium nitrate (w23%), and elemental carbon (w9%), with minor contributions from soil dust (w3%), and NO2 (w1%). High secondary inorganic aerosol contributions (i.e., SO4� and NO3 ) were the main contributors for VR <5 km. A Positive Matrix Factorization (PMF) solution to the Chemical Mass Balance (CMB) receptor model showed that coal combustion was the dominant factor, accounting for w52% of the dry particle light scattering coefficient, followed by the engine exhaust factor (w31%). Other factors included biomass burning (w12%) and fugitive dust (w5%).

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