Secondary Organic Aerosol Formation from High-NOx Photo-Oxidation of Low Volatility Precursors: n-Alkanes

Smog chamber experiments were conducted to investigate secondary organic aerosol (SOA) formation from photo-oxidation of low-volatility precursors; n-alkanes were chosen as a model system. The experiments feature atmospherically relevant organic aerosol concentrations (COA). Under high-NOx condition...

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Veröffentlicht in:	Environmental science & technology 2010-03, Vol.44 (6), p.2029-2034
Hauptverfasser:	PRESTO, Albert A, MIRACOLO, Marissa A, DONAHUE, Neil M, ROBINSON, Allen L
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Schlagworte:	Applied sciences Atmospheric pollution Exact sciences and technology Pollution
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container_end_page	2034
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container_title	Environmental science & technology
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creator	PRESTO, Albert A MIRACOLO, Marissa A DONAHUE, Neil M ROBINSON, Allen L
description	Smog chamber experiments were conducted to investigate secondary organic aerosol (SOA) formation from photo-oxidation of low-volatility precursors; n-alkanes were chosen as a model system. The experiments feature atmospherically relevant organic aerosol concentrations (COA). Under high-NOx conditions SOA yields increased with increasing carbon number (lower volatility) for n-decane, n-dodecane, n-pentadecane, and n-heptadecane, reaching a yield of 0.51 for heptadecane at a COA of 15.4 mg m-3. As with other photo-oxidation systems, aerosol yield increased with UV intensity. Due to the log-linear relationship between n-alkane carbon number and vapor pressure as well as a relatively consistent product distribution it was possible to develop an empirical parametrization for SOA yields for n-alkanes between C12 and C17. This parametrization was implemented using the volatility basis set framework and is designed for use in chemical transport models. For COA < 2 mg m-3, the SOA mass spectrum, as measured with an aerosol mass spectrometer, had a large contribution from m/z 44, indicative of highly oxygenated products. At higher COA, the mass spectrum was dominated by m/z 30, indicative of organic nitrates. The data support the conclusion that lower volatility organic vapors are important SOA precursors.
doi_str_mv	10.1021/es903712r
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The experiments feature atmospherically relevant organic aerosol concentrations (COA). Under high-NOx conditions SOA yields increased with increasing carbon number (lower volatility) for n-decane, n-dodecane, n-pentadecane, and n-heptadecane, reaching a yield of 0.51 for heptadecane at a COA of 15.4 mg m-3. As with other photo-oxidation systems, aerosol yield increased with UV intensity. Due to the log-linear relationship between n-alkane carbon number and vapor pressure as well as a relatively consistent product distribution it was possible to develop an empirical parametrization for SOA yields for n-alkanes between C12 and C17. This parametrization was implemented using the volatility basis set framework and is designed for use in chemical transport models. For COA < 2 mg m-3, the SOA mass spectrum, as measured with an aerosol mass spectrometer, had a large contribution from m/z 44, indicative of highly oxygenated products. At higher COA, the mass spectrum was dominated by m/z 30, indicative of organic nitrates. 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At higher COA, the mass spectrum was dominated by m/z 30, indicative of organic nitrates. 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title	Secondary Organic Aerosol Formation from High-NOx Photo-Oxidation of Low Volatility Precursors: n-Alkanes
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