TY - JOUR
T1 - High Contribution of Secondary Formation to Brown Carbon in China Humid Haze
T2 - Enhancing Role of Ammonia and Amines
AU - Xiao, Binyu
AU - Wang, Gehui
AU - Li, Zheng
AU - Li, Rongjie
AU - Liang, Chenlong
AU - Wang, Haoyang
AU - Zhang, Si
AU - Wu, Can
AU - Li, Rui
AU - Zhang, Fan
AU - Zhang, Renjian
AU - Wu, Yunfei
AU - Zhang, Lei
PY - 2025/12/23
Y1 - 2025/12/23
N2 - To better understand the sources and formation mechanisms of atmospheric brown carbon (BrC) in China haze, an intensive field observation was conducted in the North China Plain (NCP) during the 2023 winter. Our results showed that compared to that (28%) in dry haze, the contribution of secondary formation to BrC was significantly enhanced during humid haze, accounting for 46% of BrC production with the aqueous-phase reaction as the dominant formation pathway. The strong correlations between light absorption at λ365nm and water-soluble organic nitrogen compounds, particularly imidazoles (IMs), indicated a key role of nitrogen-containing organic compounds in the aqueous-phase BrC formation process. In the humid haze, IMs are largely produced by liquid-phase reactions of carbonyls with amines and free ammonia (NH3(aq)), which accounted for 57% of the total IMs in the humid haze events. Amines produced IMs more efficiently and less pH dependent than NH3(aq), with alkyl IMs and oxidized IMs being their products, respectively. Both types of BrC increased with increasing levels of amines and NH3(aq) during humid haze, suggesting their enhancing roles in BrC formation in China haze, which should be accounted for by models for better simulating the physicochemical characteristics and climate effects of atmospheric BrC.
AB - To better understand the sources and formation mechanisms of atmospheric brown carbon (BrC) in China haze, an intensive field observation was conducted in the North China Plain (NCP) during the 2023 winter. Our results showed that compared to that (28%) in dry haze, the contribution of secondary formation to BrC was significantly enhanced during humid haze, accounting for 46% of BrC production with the aqueous-phase reaction as the dominant formation pathway. The strong correlations between light absorption at λ365nm and water-soluble organic nitrogen compounds, particularly imidazoles (IMs), indicated a key role of nitrogen-containing organic compounds in the aqueous-phase BrC formation process. In the humid haze, IMs are largely produced by liquid-phase reactions of carbonyls with amines and free ammonia (NH3(aq)), which accounted for 57% of the total IMs in the humid haze events. Amines produced IMs more efficiently and less pH dependent than NH3(aq), with alkyl IMs and oxidized IMs being their products, respectively. Both types of BrC increased with increasing levels of amines and NH3(aq) during humid haze, suggesting their enhancing roles in BrC formation in China haze, which should be accounted for by models for better simulating the physicochemical characteristics and climate effects of atmospheric BrC.
KW - acidity
KW - aqueous-phase reaction
KW - light absorption
KW - nitrogen-containing organic compounds
KW - secondary brown carbon
UR - https://www.scopus.com/pages/publications/105025642790
U2 - 10.1021/acs.est.5c13436
DO - 10.1021/acs.est.5c13436
M3 - 文章
C2 - 41388988
AN - SCOPUS:105025642790
SN - 0013-936X
VL - 59
SP - 27530
EP - 27540
JO - Environmental Science and Technology
JF - Environmental Science and Technology
IS - 50
ER -
