{"title":"模拟室内环境变量对二次有机气溶胶形成的影响。","authors":"Spencer Blau, Myoseon Jang","doi":"10.1016/j.scitotenv.2024.177036","DOIUrl":null,"url":null,"abstract":"<p><p>There are numerous air pollutants indoors including chemicals emitted from building environments as well as outdoor-origin species due to human activities. Despite the significance of indoor air quality, the atmospheric process indoors is not well studied. In this study, the secondary organic aerosol (SOA) formation from the oxidation of α-pinene blended with toluene was simulated under varying indoor environments (lamps, NO<sub>2</sub>, ozone, and inorganic seed) using the UNIfied Partitioning Aerosol Reaction (UNIPAR) model. Explicitly predicted lumping species produced during the atmospheric oxidation of precursors are used in the model and they process multiphase partitioning and aerosol phase reactions. The performance of the model was demonstrated using indoor chamber experiments in both dark conditions (ozonolysis) and light conditions with commercialized fluorescent or LED lamps. α-Pinene SOA was dominated by ozonolysis even in the presence of indoor light. Toluene, which is known to be photochemically processed, was oxidized in the dark condition with OH radicals that were derived from ozonolysis products of α-pinene. At given dark simulation conditions (10 ppb α-pinene, 30 ppb ozone, and 50 ppb of toluene), toluene contributed 15 % of SOA mass. α-Pinene SOA was insensitive to hygroscopicity of inorganic seed, but toluene blended with α-pinene increased the sensitivity to seed conditions due to the formation of oligomeric matter via aqueous reactions of reactive toluene products. In the presence of NO<sub>2</sub>. α-pinene SOA formation significantly increased with increasing NO<sub>2</sub> owing to the reaction of α-pinene with nitrate radicals to form low volatile products. This study concludes that ozone and NO<sub>2</sub>, intruded from outdoors to indoors, effectively oxidize terpenes and furthermore aromatic hydrocarbons with OH radicals originating from ozonolysis of terpenes. The reaction paths with ozone and nitrate radicals are more effective at forming SOA than that with OH radical under the indoor light condition with commercialized lamps.</p>","PeriodicalId":422,"journal":{"name":"Science of the Total Environment","volume":"955 ","pages":"177036"},"PeriodicalIF":8.2000,"publicationDate":"2024-12-10","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Modeling impacts of indoor environmental variables on secondary organic aerosol formation.\",\"authors\":\"Spencer Blau, Myoseon Jang\",\"doi\":\"10.1016/j.scitotenv.2024.177036\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>There are numerous air pollutants indoors including chemicals emitted from building environments as well as outdoor-origin species due to human activities. Despite the significance of indoor air quality, the atmospheric process indoors is not well studied. In this study, the secondary organic aerosol (SOA) formation from the oxidation of α-pinene blended with toluene was simulated under varying indoor environments (lamps, NO<sub>2</sub>, ozone, and inorganic seed) using the UNIfied Partitioning Aerosol Reaction (UNIPAR) model. Explicitly predicted lumping species produced during the atmospheric oxidation of precursors are used in the model and they process multiphase partitioning and aerosol phase reactions. The performance of the model was demonstrated using indoor chamber experiments in both dark conditions (ozonolysis) and light conditions with commercialized fluorescent or LED lamps. α-Pinene SOA was dominated by ozonolysis even in the presence of indoor light. Toluene, which is known to be photochemically processed, was oxidized in the dark condition with OH radicals that were derived from ozonolysis products of α-pinene. At given dark simulation conditions (10 ppb α-pinene, 30 ppb ozone, and 50 ppb of toluene), toluene contributed 15 % of SOA mass. α-Pinene SOA was insensitive to hygroscopicity of inorganic seed, but toluene blended with α-pinene increased the sensitivity to seed conditions due to the formation of oligomeric matter via aqueous reactions of reactive toluene products. In the presence of NO<sub>2</sub>. α-pinene SOA formation significantly increased with increasing NO<sub>2</sub> owing to the reaction of α-pinene with nitrate radicals to form low volatile products. This study concludes that ozone and NO<sub>2</sub>, intruded from outdoors to indoors, effectively oxidize terpenes and furthermore aromatic hydrocarbons with OH radicals originating from ozonolysis of terpenes. 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引用次数: 0
摘要
室内有许多空气污染物,包括从建筑环境中排放的化学物质以及因人类活动而产生的室外污染物。尽管室内空气质量非常重要,但对室内大气过程的研究却不多。在这项研究中,我们使用 UNIfied Partitioning Aerosol Reaction(UNIPAR)模型模拟了在(灯、二氧化氮、臭氧和无机种子)不同的室内环境下,α-蒎烯与甲苯混合氧化形成的二次有机气溶胶(SOA)。模型中使用了明确预测的前体在大气氧化过程中产生的块状物质,它们处理多相分区和气溶胶相反应。该模型的性能通过在黑暗条件(臭氧分解)和使用商用荧光灯或 LED 灯的光照条件下进行的室内试验室实验得到了验证。已知经过光化学处理的甲苯在黑暗条件下被α-蒎烯臭氧分解产物产生的羟基氧化。在给定的黑暗模拟条件下(10 ppb α-蒎烯、30 ppb 臭氧和 50 ppb 甲苯),甲苯占 SOA 质量的 15%。α-蒎烯 SOA 对无机种子的吸湿性不敏感,但甲苯与 α-蒎烯混合后会增加对种子条件的敏感性,这是因为反应性甲苯产物的水反应会形成低聚物。在二氧化氮存在的情况下,α-蒎烯 SOA 的形成随着二氧化氮的增加而显著增加,这是由于α-蒎烯与硝酸根自由基反应形成了低挥发性产物。这项研究的结论是,从室外侵入室内的臭氧和二氧化氮能有效地氧化萜烯,并利用萜烯臭氧分解产生的羟自由基进一步氧化芳香烃。在使用商业化灯具的室内光照条件下,臭氧和硝酸根的反应路径比羟基更有效地形成 SOA。
Modeling impacts of indoor environmental variables on secondary organic aerosol formation.
There are numerous air pollutants indoors including chemicals emitted from building environments as well as outdoor-origin species due to human activities. Despite the significance of indoor air quality, the atmospheric process indoors is not well studied. In this study, the secondary organic aerosol (SOA) formation from the oxidation of α-pinene blended with toluene was simulated under varying indoor environments (lamps, NO2, ozone, and inorganic seed) using the UNIfied Partitioning Aerosol Reaction (UNIPAR) model. Explicitly predicted lumping species produced during the atmospheric oxidation of precursors are used in the model and they process multiphase partitioning and aerosol phase reactions. The performance of the model was demonstrated using indoor chamber experiments in both dark conditions (ozonolysis) and light conditions with commercialized fluorescent or LED lamps. α-Pinene SOA was dominated by ozonolysis even in the presence of indoor light. Toluene, which is known to be photochemically processed, was oxidized in the dark condition with OH radicals that were derived from ozonolysis products of α-pinene. At given dark simulation conditions (10 ppb α-pinene, 30 ppb ozone, and 50 ppb of toluene), toluene contributed 15 % of SOA mass. α-Pinene SOA was insensitive to hygroscopicity of inorganic seed, but toluene blended with α-pinene increased the sensitivity to seed conditions due to the formation of oligomeric matter via aqueous reactions of reactive toluene products. In the presence of NO2. α-pinene SOA formation significantly increased with increasing NO2 owing to the reaction of α-pinene with nitrate radicals to form low volatile products. This study concludes that ozone and NO2, intruded from outdoors to indoors, effectively oxidize terpenes and furthermore aromatic hydrocarbons with OH radicals originating from ozonolysis of terpenes. The reaction paths with ozone and nitrate radicals are more effective at forming SOA than that with OH radical under the indoor light condition with commercialized lamps.
期刊介绍:
The Science of the Total Environment is an international journal dedicated to scientific research on the environment and its interaction with humanity. It covers a wide range of disciplines and seeks to publish innovative, hypothesis-driven, and impactful research that explores the entire environment, including the atmosphere, lithosphere, hydrosphere, biosphere, and anthroposphere.
The journal's updated Aims & Scope emphasizes the importance of interdisciplinary environmental research with broad impact. Priority is given to studies that advance fundamental understanding and explore the interconnectedness of multiple environmental spheres. Field studies are preferred, while laboratory experiments must demonstrate significant methodological advancements or mechanistic insights with direct relevance to the environment.
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