Abstract
Abstract. The effects of SO2 and NH3 on secondary organic aerosol formation have rarely been investigated together, while the interactive effects between inorganic and organic species under highly complex pollution conditions remain uncertain. Here we studied the effects of SO2 and NH3 on secondary aerosol formation in the photooxidation system of toluene∕NOx in the presence or absence of Al2O3 seed aerosols in a 2 m3 smog chamber. The presence of SO2 increased new particle formation and particle growth significantly, regardless of whether NH3 was present. Sulfate, organic aerosol, nitrate, and ammonium were all found to increase linearly with increasing SO2 concentrations. The increases in these four species were more obvious under NH3-rich conditions, and the generation of nitrate, ammonium, and organic aerosol increased more significantly than sulfate with respect to SO2 concentration, while sulfate was the most sensitive species under NH3-poor conditions. The synergistic effects between SO2 and NH3 in the heterogeneous process contributed greatly to secondary aerosol formation. Specifically, the generation of NH4NO3 was found to be highly dependent on the surface area concentration of suspended particles, and increased most significantly with SO2 concentration among the four species under NH3-rich conditions. Meanwhile, the absorbed NH3 might provide a liquid surface layer for the absorption and subsequent reaction of SO2 and organic products and, therefore, enhance sulfate and secondary organic aerosol (SOA) formation. This effect mainly occurred in the heterogeneous process and resulted in a significantly higher growth rate of seed aerosols compared to without NH3. By applying positive matrix factorisation (PMF) analysis to the AMS data, two factors were identified for the generated SOA. One factor, assigned to less-oxidised organic aerosol and some oligomers, increased with increasing SO2 under NH3-poor conditions, mainly due to the well-known acid catalytic effect of the acid products on SOA formation in the heterogeneous process. The other factor, assigned to the highly oxidised organic component and some nitrogen-containing organics (NOC), increased with SO2 under a NH3-rich environment, with NOC (organonitrates and NOC with reduced N) contributing most of the increase.
Highlights
With the recent rapid economic development and urbanisation, the associated emissions from coal combustion, motor vehicle exhaust, and various industrial emissions have led to highly complex air pollution in China
The effects of SO2 and NH3 on secondary aerosol formation were qualitatively studied in the photooxidation system of toluene/NOx without the presence of a seed aerosol
∗ Calculated according to the amount of NH3 introduced and the volume of the reactor. Another synergetic effect we found in secondary inorganic aerosol formation was that sulfate formation was enhanced by the presence of NH3
Summary
With the recent rapid economic development and urbanisation, the associated emissions from coal combustion, motor vehicle exhaust, and various industrial emissions have led to highly complex air pollution in China. A few studies have reported high concentrations of NH3 (maximum concentration higher than 100 ppb) in the North China Plain (Meng et al, 2015; Wen et al, 2015) and many observational data indicated NH3-rich conditions for secondary aerosol formation, strong correlations between peak levels of fine particles and large increases in NH3 concentrations in China Unlike SO2, the emission of NH3 is mainly from non-point sources, which are difficult to control, and show an increasing trend in China (Dong, 2010) Under this complex situation, studying the synergistic effects of SO2 and NH3 in secondary aerosol formation is crucial for understanding the formation mechanism for heavy haze pollution
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
