Air humidity affects secondary aerosol formation in different pathways

Haze pollution characteristics and PM2.5 chemical composition were distinctive in different air humiditydependent haze episodes in winter of North China Plain (NCP). The impact of air humidity on particulate chemical compositionwas investigated based on the in situ observation inwinter of 2017-2018 in Tianjin. Relative humidity (RH) and absolute humidity affect the secondary aerosol generation in differentways. Particularly, nitrate changesmore obviously with absolute humidity, while sulfate changes more obviously with RH. In the daytime, at certain conditions, high water vapor content, O-3 concentration and stronger solar radiation may promote the gas-phase oxidation of NOx by the addition of OH formed though O-3 photolysis, especially during the transition periods between winter and autumn or spring. Whereas in the nighttime, temperature drop generated the high RH, which was favorable for the gas-particle portioning of HNO3 and the occurrence of the N2O5 heterogeneous hydrolysis reaction. At lower temperature and higher RH (T< 0 degrees C, RH> 80%) condition, SO42 - mass fraction was relatively higher. Lower temperature can result inmore SO2 dissolved in equilibriumand the relatively higher initial aerosol pH, which both generate faster aqueous oxidation rate. Given the currently low SO2 concentration in the regional scale, the meteorological condition in which the occurrence of sulfate formation through aqueous reaction may be more stringent. (C) 2020 Elsevier B.V. All rights reserved.

Automated summary

This study found that air humidity had a significant impact on particulate chemical composition during winter haze episodes in North China Plain, with nitrate being more related to absolute humidity and sulfate being more related to relative humidity. Daytime high water vapor content and solar radiation promoted oxidation of NOx, while nighttime temperature drop favored nitric acid and N2O5 reactions.