• 综述 •
王玉珏, 胡敏, 李晓, 徐楠. 大气颗粒物中棕色碳的化学组成、来源和生成机制[J]. 化学进展, 2020, 32(5): 627-641.
Yujue Wang, Min Hu, Xiao Li, Nan Xu. Chemical Composition, Sources and Formation Mechanisms of Particulate Brown Carbon in the Atmosphere[J]. Progress in Chemistry, 2020, 32(5): 627-641.
大气颗粒物中棕色碳(BrC)在近紫外波段具有强吸光性,并因其显著的气候效应被广泛关注。BrC组成、来源、演变和光学性质的不确定性是造成气候模型估算气溶胶辐射强迫不确定性的重要因素。本文综述了大气颗粒物中BrC的化学组成、来源和生成机制,聚焦分子水平上BrC组成、二次生成机制和吸光间的关联。大气颗粒物中BrC的主要类别包括有机溶剂(甲醇)提取的碳质组分、水溶性有机碳及类腐殖质; 分子水平上,硝基芳香烃和含氮杂环有机物是BrC的主要发色团。BrC的来源包括生物质等不完全燃烧一次排放和挥发性有机物氧化二次生成; 二次生成途径主要包括人为源芳香烃氧化生成硝基芳香烃等含氮组分、羰基化合物与铵/胺反应生成含氮杂环组分或低聚物。前体物和反应条件影响二次生成BrC的组成和吸光性质; BrC在大气传输过程中还会发生“光漂白”现象。在分子水平上识别和阐明BrC的发色团、二次生成机制及其演变过程是未来该领域的重点研究方向。
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Formula | Sources | ref | Formula | Sources | ref | |||
---|---|---|---|---|---|---|---|---|
Oxidation of aromatic VOCs | Biomass burning | MG+AS a | Biomass burning | MG+AS a | ||||
C5H4N2O5 | √ | 21 | C13H13NO3 | √ | 84 | |||
C6H3N3O7 | √ | 21 | C13H13NO4 | √ | 86 | |||
C6H4N2O5 | √ | 21 | C15H23N3O2 | √ | 91 | |||
C6H4N2O6 | √ | 21, 92 | C16H9NO3 | √ | 84 | |||
C6H5NO2 | √ | 21 | C17H11N | √ | 86 | |||
C6H5NO3 | √ | √ | 17, 21, 85, 87, 90, 92 | C18H27NO5 | √ | 84 | ||
C6H5NO4 | √ | √ | 17, 84, 85, 87, 90, 92 | C21H11N | √ | 84, 86 | ||
C6H5NO5 | √ | √ | 84~86, 92 | C21H13N | √ | 84 | ||
C6H6N2O6 | √ | 21 | C22H34N2O6 | √ | 84 | |||
C7H4N2O6 | √ | 21 | C23H13N | √ | 84 | |||
C7H4N2O7 | √ | 21 | C23H31NO4 | √ | 84 | |||
C7H5NO6 | √ | 21 | C27H39NO2 | √ | 84 | |||
C7H6N2O6 | √ | 21, 92 | C48H66N4O4 | √ | 84 | |||
C7H7NO2 | √ | 21 | C6H7NO2 | √ | 88 | |||
C7H7NO3 | √ | √ | 17, 21, 85, 87, 90~92 | C6H8N2 | √ | 88 | ||
C7H7NO4 | √ | √ | 17, 21, 84~87, 90~92 | C6H8N2O | √ | 88 | ||
C7H7NO5 | √ | √ | 21, 84, 85, 87, 92 | C6H9NO3 | √ | 88 | ||
C7H8N2O7 | √ | 21 | C7H10N2O | √ | 88 | |||
C7H9NO5 | √ | 21 | C8H10N2O | √ | 88 | |||
C8H7NO4 | √ | √ | 17, 84, 86, 92 | C8H11NO | √ | 88 | ||
C8H8N2O5 | √ | 21 | C8H11NO3 | √ | 88 | |||
C8H9NO4 | √ | √ | 85~87, 92 | C8H12N2O | √ | 88 | ||
C8H9NO5 | √ | √ | 17, 84~87, 92 | C8H7NO2 | √ | 88 | ||
C8H13NO8 | √ | 21 | C9H11N3 | √ | 88 | |||
C9H9NO4 | √ | √ | 17, 85, 87, 92 | C9H11N3O | √ | 88 | ||
C10H7NO4 | √ | 92 | C9H11NO3 | √ | 88 | |||
C5H4N2O3 | √ | 85 | C9H12N2O | √ | 88 | |||
C5H5NO4 | √ | 85 | C9H9NO3 | √ | 88 | |||
C6H4N2O5 | √ | 85, 90 | C10H11NO2 | √ | 88 | |||
C6H6N2O3 | √ | 85 | C10H13N3O | √ | 88 | |||
C7H5NO5 | √ | 85, 91, 92 | C10H14N2O4 | √ | 88 | |||
C7H6N2O5 | √ | 85 | C11H14N2O3 | √ | 88 | |||
C8H5NO4 | √ | 85 | C11H14N2O4 | √ | 88 | |||
C8H7NO3 | √ | 84, 87 | C11H15NO6 | √ | 88 | |||
C8H8N2O5 | √ | 85 | C11H17N3O3 | √ | 88 | |||
C8H9NO3 | √ | 85, 91 | C12H14N2O3 | √ | 88 | |||
C9H11NO4 | √ | √ | 85, 86, 88 | C12H14N2O4 | √ | 88 | ||
C9H7NO3 | √ | 84 | C12H15N3O3 | √ | 88 | |||
C9H7NO4 | √ | 84, 85 | C12H16N2O4 | √ | 88 | |||
C9H9NO5 | √ | 85 | C12H16N2O5 | √ | 88 | |||
C10H10N2O7 | √ | 85 | C13H16N2O2 | √ | 88 | |||
C10H11NO4 | √ | 85 | C13H17N3O3 | √ | 88 | |||
C10H11NO5 | √ | 85, 86 | C13H18N2O6 | √ | 88 | |||
C10H13NO4 | √ | 86 | C14H16N2O2 | √ | 88 | |||
C10H7NO3 | √ | 84~86, 92 | C14H17N3O3 | √ | 88 | |||
C10H7NO5 | √ | 85 | C15H17N3O3 | √ | 88 | |||
C10H8N2O3 | √ | 85 | C15H19NO6 | √ | 88 | |||
C10H9NO5 | √ | 85 | C15H21N3O6 | √ | 88 | |||
C11H11NO4 | √ | 85 | C15H21NO7 | √ | 88 | |||
C11H13NO4 | √ | 86 | C17H19NO5 | √ | 88 | |||
C11H13NO5 | √ | 86 | C17H20N2O6 | √ | 88 | |||
C11H9NO3 | √ | 84 | C17H20N2O7 | √ | 88 | |||
C12H11NO3 | √ | 84 | C18H23N3O5 | √ | 88 |
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