Source:Atmospheric Environment, Volume 154
Author(s): Jialiang Nan, Shanshan Wang, Yanlin Guo, Yajing Xiang, Bin Zhou
To investigate on the daytime OH and its implication to fine particle, the long-path differential optical absorption spectroscopy (LP-DOAS) system was employed to observe the main OH precursors of O3, HCHO and HONO, as well as NO2 and NO3 radical from April to August 2013 over Shanghai, China. The main OH production paths from HONO, HCHO and O3 were estimated to be occupied around 57.6%, 30.5% and 11.9% during daytime. The daytime OH radical concentration under steady-state was averaged at 1.02 × 107 molec cm−3, which was significantly impacted by the photolytic processes. The relationship between photolysis frequency j(O1D) and OH radical suggests that heavy fine particle loads can make the photolytic reactions less efficiently and decrease the OH production and concentration. Utilizing CO as the indicator, the part of PM2.5 mass related to primary emitted sources was found less impacted by the OH levels. The contribution of secondary organic aerosol with metrics of O3 was enhanced with the increases of the OH levels, while secondary inorganic part of PM2.5 was favor of the condition that smaller OH concentrations that 5 × 105–5 × 106 molec cm−3. Meantime, a simplified multivariate model was employed to evaluate the influences of OH levels on different parts of fine particles related to different emission and sources. Normalized by solar radiation, this part of OH unrelated to radiation was found to be inversely related to the PM2.5, which indicates the self-cleansing capability of the atmosphere.
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