Chemical Composition of Fresh and Aged Asphalt-Related Organic Aerosols: From Ambient Observations to Laboratory Experiments

ACS ES&T Air Pub Date : 2025-03-25 DOI:10.1021/acsestair.4c0019310.1021/acsestair.4c00193

Peeyush Khare, Jo Machesky, Leah Williams, Mackenzie Humes, Edward C. Fortner, Manjula Canagaratna, Jordan E. Krechmer, Andrew T. Lambe, Albert A. Presto and Drew R. Gentner*,

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Abstract

Asphalt-related emissions are an understudied source of reactive organic compounds with the potential to form organic aerosol (OA). Ambient aerosol mass spectrometry (AMS) measurements of asphalt-related aerosols near a month-long road paving project showed enhanced ambient OA concentrations with a mix of primary and secondary OA signatures. For comparison, gas-phase emissions from real-world road asphalt samples at application (e.g., 140 °C) and in-use (e.g., 60 °C) temperatures were injected into an environmental chamber and an oxidation flow reactor to simulate varying degrees of oxidative aging while measuring their gas- and aerosol-phase oxidation products. Secondary OA formation was observed via both self-nucleation and condensation, with chemical properties dependent on asphalt temperature and reaction conditions. The chemical composition of less-aged asphalt-related OA observed in outdoor and laboratory measurements was similar to OA from other petrochemical-based sources and hydrocarbon-like OA source factors observed via AMS in previous urban studies. The composition of aged OA varied with the degree of oxidation, similar to oxidized OA factors observed in ambient air. Taken together, these field and laboratory observations suggest that contributions to urban OA during and after application may be challenging to deconvolve from other traditional sources in ambient measurements.

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新鲜和老化沥青相关有机气溶胶的化学成分：从环境观察到实验室实验

与沥青相关的排放物是一种活性有机化合物的未充分研究来源，具有形成有机气溶胶（OA）的潜力。在一个长达一个月的道路铺设项目附近，环境气溶胶质谱（AMS）测量了与沥青相关的气溶胶，结果显示环境OA浓度增加，并伴有初级和次级OA特征。为了进行比较，将实际道路沥青样品在应用温度（例如140°C）和使用温度（例如60°C）下的气相排放注入环境室和氧化流反应器中，以模拟不同程度的氧化老化，同时测量其气相和气溶胶相氧化产物。通过自成核和缩聚两种方式观察到次生OA形成，其化学性质取决于沥青温度和反应条件。在室外和实验室测量中观察到的年龄较小的沥青相关OA的化学成分与之前通过AMS在城市研究中观察到的其他石化来源的OA和碳氢化合物源因素相似。老化OA的组成随氧化程度而变化，类似于在环境空气中观察到的氧化OA因子。综上所述，这些实地和实验室观测结果表明，在应用期间和应用后，对城市OA的贡献可能难以从环境测量中的其他传统来源进行反卷积。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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ACS ES&T Air

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