Reactive aldehyde chemistry explains the missing source of hydroxyl radicals

• Published in: Nature communications Vol. 15; no. 1; pp. 1648 - 8
• Main Authors: Yang, Xinping, Wang, Haichao, Lu, Keding, Ma, Xuefei, Tan, Zhaofeng, Long, Bo, Chen, Xiaorui, Li, Chunmeng, Zhai, Tianyu, Li, Yang, Qu, Kun, Xia, Yu, Zhang, Yuqiong, Li, Xin, Chen, Shiyi, Dong, Huabin, Zeng, Limin, Zhang, Yuanhang
• Format: Journal Article
• Language: English
• Published: London Nature Publishing Group UK 22.02.2024; Nature Publishing Group; Nature Portfolio
• Subjects: 119/118; 140/125; 704/106/35/824; 704/172/169; Air quality; Aldehydes; Anthropogenic factors; Atmospheric chemistry; Autoxidation; Carbonyl compounds; Carbonyls; Chemistry; Free radicals; Human influences; Humanities and Social Sciences; Hydroxyl radicals; Isoprene; multidisciplinary; Nitrogen oxides; Organic compounds; Peroxy radicals; Photochemicals; Photolysis; Quantum chemistry; Science; Science (multidisciplinary); Troposphere; VOCs; Volatile organic compounds
• ISSN: 2041-1723; 2041-1723
• DOI: 10.1038/s41467-024-45885-w

Hydroxyl radicals (OH) determine the tropospheric self-cleansing capacity, thus regulating air quality and climate. However, the state-of-the-art mechanisms still underestimate OH at low nitrogen oxide and high volatile organic compound regimes even considering the latest isoprene chemistry. Here we propose that the reactive aldehyde chemistry, especially the autoxidation of carbonyl organic peroxy radicals (R(CO)O 2 ) derived from higher aldehydes, is a noteworthy OH regeneration mechanism that overwhelms the contribution of the isoprene autoxidation, the latter has been proved to largely contribute to the missing OH source under high isoprene condition. As diagnosed by the quantum chemical calculations, the R(CO)O 2 radicals undergo fast H-migration to produce unsaturated hydroperoxyl-carbonyls that generate OH through rapid photolysis. This chemistry could explain almost all unknown OH sources in areas rich in both natural and anthropogenic emissions in the warm seasons, and may increasingly impact the global self-cleansing capacity in a future low nitrogen oxide society under carbon neutrality scenarios. Hydroxyl radicals (OH) determine the tropospheric self-cleansing capacity. This study reveals that reactive aldehyde chemistry plays an important role in OH formation and helps narrow the gap between ambient OH observations and model simulations.