Bowen He, Shicong Du, Zhu Ran, Yiqun Wang, Qingxin Deng, Jinli Xu, Yan Ren, Adrien Gandolfo, Mingjin Tang, Theodora Nah, Manolis N. Romanías, Jiangping Liu, Xinming Wang, Patrick K. H. Lee, Sasho Gligorovski

doi:10.1021/acs.estlett.5c00949

Summary

Mineral dust particles are omnipresent in the atmosphere all over the globe. Nitrogen dioxide (NO2) can be adsorbed on the dust surface and converted to nitrous acid (HONO), which in turn represents one of the most important sources of hydroxyl radicals (OH) driving the oxidation capacity of the atmosphere. Here, we evaluate the conversion of NO2 to HONO on mineral dust samples from different regions of the world. We reveal that the synergistic effects of relative humidity (RH), UV-light, titanium dioxide (TiO2), and microbes present on the mineral dust surface are responsible for the observed high HONO yields. The light-induced uptake coefficients of NO2 on mineral dust surface are 1 order of magnitude higher than the uptakes measured in the dark. Intriguingly, the uptakes of NO2 are high

Source type: Peer-reviewed study
DOI: 10.1021/acs.estlett.5c00949
Catalogue ID: SNmoht1tuo-ntkub7

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Revisiting HONO Formation Mechanism by NO <sub>2</sub> Conversion on Mineral Dust Surface

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