大气中烷基取代的多环芳烃(AlkPAHs)的异相臭氧分解†。

IF 2.8 Q3 ENVIRONMENTAL SCIENCES
Vera Zaherddine, Elisabeth Galarneau and Arthur W. H. Chan
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引用次数: 0

摘要

多环芳烃化合物 (PAC) 包含一系列有机污染物,包括多环芳烃 (PAHs)、烷基取代多环芳烃 (AlkPAHs) 等。由于 PAHs 对环境和健康的影响,人们对其进行了广泛的研究。然而,烷基多环芳烃受到的关注相对较少,尽管最近有证据表明它们在环境空气中的含量更高。鉴于烷基PAHs 的普遍性和潜在风险,研究烷基PAHs 在大气中的转化至关重要。这项研究的重点是烷基PAHs 的异相氧化,特别是烷基对反应动力学的影响。气相臭氧的氧化作用是在石英过滤器上进行的,石英过滤器是二氧化硅表面的模型,PAC 可沉积在其上,化学作用极小。结果表明,烷基多环芳烃与臭氧的反应速度比多环芳烃快,烷基取代度越高,反应速度越快。此外,在 1-甲基芘的氧化过程中还形成了含氧多环芳烃(OPAHs),其多样性高于芘。与母体化合物相比,这些产物的极性更大,潜在毒性也更强。总之,这项研究推进了我们对 PAC 氧化的了解,重点关注 AlkPAHs 的异质氧化、烷基的影响以及 OPAHs 的形成。这些见解对空气质量、健康风险评估以及 PAC 在环境中的归宿具有重要意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Heterogeneous ozonolysis of alkyl substituted-polycyclic aromatic hydrocarbons (AlkPAHs) in the atmosphere†

Heterogeneous ozonolysis of alkyl substituted-polycyclic aromatic hydrocarbons (AlkPAHs) in the atmosphere†

Polycyclic aromatic compounds (PACs) encompass a range of organic pollutants, including polycyclic aromatic hydrocarbons (PAHs), alkyl-substituted PAHs (AlkPAHs), and others. PAHs have been extensively studied due to their environmental and health implications. AlkPAHs, however, have received relatively less attention, despite recent evidence suggesting their greater abundances in ambient air. Given their prevalence and potential risks, investigating the atmospheric transformation of AlkPAHs is crucial. This work focuses on the heterogeneous oxidation of AlkPAHs, specifically addressing the influence of alkyl groups on reaction kinetics. Oxidation by gas phase ozone was conducted on quartz filters, which serve as models for silica surfaces on which PACs can deposit with minimal chemical interactions. The results reveal that AlkPAHs react faster with ozone than PAHs do, with reaction rates increasing with higher alkyl group substitutions. Furthermore, oxygenated polycyclic aromatic hydrocarbons (OPAHs) were formed during the oxidation of 1-methylpyrene, with greater diversity than those from pyrene. These products are more polar and potentially more toxic than parent compounds. In conclusion, this research advances our understanding of PAC oxidation, focusing on AlkPAHs' heterogeneous oxidation, the influence of alkyl groups, and the formation of OPAHs. These insights have significant implications for air quality, health risk assessments, and the fate of PACs in the environment.

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