The Key Role of Sulfate in the Photochemical Renoxification on Real PM2.5

The active nitrogen species (HONO, NO, and NO2) have important impacts on the atmospheric oxidative capacity and the transformation of many atmospheric species. In this study, a fast photochemical renoxification rate of adsorbed HNO3/NO3 – to active nitrogen species (HONO, NO, and NO2) was detected...

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Bibliographic Details
Published in:Environmental science & technology 2020-03, Vol.54 (6), p.3121-3128
Main Authors: Bao, Fengxia, Jiang, Hongyu, Zhang, Yue, Li, Meng, Ye, Chunxiang, Wang, Weigang, Ge, Maofa, Chen, Chuncheng, Zhao, Jincai
Format: Article
Language:English
Subjects:
Nitrogen
Nitrogen cycle
Nitrogen dioxide
Nitrogen oxides
Particulate matter
Particulates
Photochemical reactions
Photochemicals
Photolysis
Photosensitization
Protons
Species
Sulfates
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Summary:The active nitrogen species (HONO, NO, and NO2) have important impacts on the atmospheric oxidative capacity and the transformation of many atmospheric species. In this study, a fast photochemical renoxification rate of adsorbed HNO3/NO3 – to active nitrogen species (HONO, NO, and NO2) was detected on real urban PM2.5, and sulfate was found to play a key role in this process. Different from the reported direct photolysis pathway, the photochemical reaction of HNO3/NO3 – on PM2.5 is dominated by a photosensitizing mechanism. Acidic protons are proved to be essential for this pathway. The role of sulfate, because of the nonvolatility of its conjugated acid, is to conserve the necessary acidic protons when interacting with HNO3 and thus maintain its photoreactivity. This work implies that sulfate will have important implications in atmospheric nitrogen cycling by accelerating the release of nitrogen oxides from photochemical renoxification of HNO3/NO3 – adsorbed on ambient particulates and thus can cause major environmental problems.
ISSN:0013-936X
1520-5851
DOI:10.1021/acs.est.9b06764