Abstract
Abstract. Laboratory chambers, invaluable in atmospheric chemistry and aerosol formation studies, are subject to particle and vapor wall deposition, processes that need to be accounted for in order to accurately determine secondary organic aerosol (SOA) mass yields. Although particle wall deposition is reasonably well understood and usually accounted for, vapor wall deposition is less so. The effects of vapor wall deposition on SOA mass yields in chamber experiments can be constrained experimentally by increasing the seed aerosol surface area to promote the preferential condensation of SOA-forming vapors onto seed aerosol. Here, we study the influence of seed aerosol surface area and oxidation rate on SOA formation in α-pinene ozonolysis. The observations are analyzed using a coupled vapor–particle dynamics model to interpret the roles of gas–particle partitioning (quasi-equilibrium vs. kinetically limited SOA growth) and α-pinene oxidation rate in influencing vapor wall deposition. We find that the SOA growth rate and mass yields are independent of seed surface area within the range of seed surface area concentrations used in this study. This behavior arises when the condensation of SOA-forming vapors is dominated by quasi-equilibrium growth. Faster α-pinene oxidation rates and higher SOA mass yields are observed at increasing O3 concentrations for the same initial α-pinene concentration. When the α-pinene oxidation rate increases relative to vapor wall deposition, rapidly produced SOA-forming oxidation products condense more readily onto seed aerosol particles, resulting in higher SOA mass yields. Our results indicate that the extent to which vapor wall deposition affects SOA mass yields depends on the particular volatility organic compound system and can be mitigated through the use of excess oxidant concentrations.
Highlights
Secondary organic aerosol (SOA), formed from the oxidation of volatile and intermediate-volatility organic compounds (VOCs and IVOCs), contributes a significant fraction of the global organic aerosol burden (Kanakidou et al, 2005; Hallquist et al, 2009; Tsigaridis et al, 2014)
We examine the influence of seed aerosol surface area and oxidation rate on SOA formation in α-pinene ozonolysis chamber experiments. α-pinene is the most abundant monoterpene, with global emissions estimated to be ∼ 66 Tg yr−1 (Guenther et al, 2012)
To study how coagulation can potentially affect SOA mass yields in this study, both the measured and coagulation-corrected sizedependent particle wall deposition coefficients are used to correct for particle wall deposition in the α-pinene ozonolysis experiments
Summary
Secondary organic aerosol (SOA), formed from the oxidation of volatile and intermediate-volatility organic compounds (VOCs and IVOCs), contributes a significant fraction of the global organic aerosol burden (Kanakidou et al, 2005; Hallquist et al, 2009; Tsigaridis et al, 2014). McVay et al (2016) reported similar SOA growth at low and high OH concentrations in α-pinene photooxidation Taken together, these studies show the importance of understanding how gas–particle partitioning and VOC oxidation rate impact vapor wall deposition and SOA mass yields in laboratory chamber experiments. We measure the α-pinene SOA mass yield as a function of seed aerosol surface area concentration (0 to 3000 μm cm−3) and O3 mixing ratio (100 vs 500 ppb) These results are analyzed using a coupled vapor–particle dynamics model to evaluate the roles of gas–particle partitioning and VOC oxidation rate in influencing vapor wall deposition effects on the measured SOA mass yields.
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