Laboratory studies of the chemical composition and cloud condensation nuclei (CCN) activity of secondary organic aerosol (SOA) and oxidized primary organic aerosol (OPOA)

Lambe, Andrew T.; Onasch, T. B.; Massoli, P.; Croasdale, D. R.; Wright, Justin P.; Ahern, Adam; Williams, Leah R.; Worsnop, D. R.; Brune, W. H.; Davidovits, P.

doi:10.5194/acpd-11-13617-2011

Cited by 95 publications

(173 citation statements)

References 71 publications

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“…Further exposure (≥ 4 × 10 11 molecules cm −3 s −1 ) does not significantly enhance MNC κ, which suggests that MNC or the particle surface is fully oxidized (Slade and Knopf, 2014) and that the reaction products reach a maximum in κ. Similar enhancements in κ and subsequent constant κ values with increasing OH exposure have been observed for organic aerosol with initially low hygroscopicity Lambe et al, 2011). For example, George et al (2009) observed that κ of BES increased from ∼ 0.008 to ∼ 0.08 for an OH exposure of ∼ 1.5 × 10 12 molecule cm −3 s, and κ of stearic acid increased from ∼ 0.004 to ∼ 0.04 due to an OH exposure of ∼ 7.5 × 10 11 molecule cm −3 s. The enhancement in MNC κ following OH exposure may be linked to the formation of more hydrophilic chemical functionalities.…”

Section: Ccn Activity Of Bba Surrogate Particlessupporting

confidence: 75%

“…For example, George et al (2009) observed that κ of BES increased from ∼ 0.008 to ∼ 0.08 for an OH exposure of ∼ 1.5 × 10 12 molecule cm −3 s, and κ of stearic acid increased from ∼ 0.004 to ∼ 0.04 due to an OH exposure of ∼ 7.5 × 10 11 molecule cm −3 s. The enhancement in MNC κ following OH exposure may be linked to the formation of more hydrophilic chemical functionalities. Strongly linked to enhancements in OA hygroscopicity are larger O : C ratios (Massoli et al, 2010;Lambe et al, 2011;Mei et al, 2013a, b;Suda et al, 2014). Neglecting the oxygen atoms in the -nitro functionality of MNC (Suda et al, 2014), the O : C ratio of pure MNC is ∼ 0.29, close to the lower end in O : C where transitions from low κ to high κ typically occur (Suda et al, 2014).…”

Section: Ccn Activity Of Bba Surrogate Particlesmentioning

confidence: 97%

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Chemical aging of single and multicomponent biomass burning aerosol surrogate particles by OH: implications for cloud condensation nucleus activity

et al. 2015

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Abstract. Multiphase OH and O 3 oxidation reactions with atmospheric organic aerosol (OA) can influence particle physicochemical properties including composition, morphology, and lifetime. Chemical aging of initially insoluble or low-soluble single-component OA by OH and O 3 can increase their water solubility and hygroscopicity, making them more active as cloud condensation nuclei (CCN) and susceptible to wet deposition. However, an outstanding problem is whether the effects of chemical aging on their CCN activity are preserved when mixed with other organic or inorganic compounds exhibiting greater water solubility. In this work, the CCN activity of laboratory-generated biomass burning aerosol (BBA) surrogate particles exposed to OH and O 3 is evaluated by determining the hygroscopicity parameter, κ, as a function of particle type, mixing state, and OH and O 3 exposure applying a CCN counter (CCNc) coupled to an aerosol flow reactor (AFR). Levoglucosan (LEV), 4-methyl-5-nitrocatechol (MNC), and potassium sulfate (KS) serve as representative BBA compounds that exhibit different hygroscopicity, water solubility, chemical functionalities, and reactivity with OH radicals, and thus exemplify the complexity of mixed inorganic/organic aerosol in the atmosphere. The CCN activities of all of the particles were unaffected by O 3 exposure. Following exposure to OH, κ of MNC was enhanced by an order of magnitude, from 0.009 to ∼ 0.1, indicating that chemically aged MNC particles are better CCN and more prone to wet deposition than pure MNC particles. No significant enhancement in κ was observed for pure LEV particles following OH exposure. κ of the internally mixed particles was not affected by OH oxidation. Furthermore, the CCN activity of OH-exposed MNCcoated KS particles is similar to the OH unexposed atomized 1 : 1 by mass MNC : KS binary-component particles. Our results strongly suggest that when OA is dominated by watersoluble organic carbon (WSOC) or inorganic ions, chemical aging has no significant impact on OA hygroscopicity. The organic compounds exhibiting low solubility behave as if they are infinitely soluble when mixed with a sufficient number of water-soluble compounds. At and beyond this point, the particles' CCN activity is governed entirely by the watersoluble fraction and is not influenced by the oxidized organic fraction. Our results have important implications for heterogeneous oxidation and its impact on cloud formation given that atmospheric aerosol is a complex mixture of organic and inorganic compounds exhibiting a wide range of solubilities.

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Section: Ccn Activity Of Bba Surrogate Particlessupporting

confidence: 75%

Section: Ccn Activity Of Bba Surrogate Particlesmentioning

confidence: 97%

Chemical aging of single and multicomponent biomass burning aerosol surrogate particles by OH: implications for cloud condensation nucleus activity

et al. 2015

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“…For T1 and T3, reductions in Δ -2 , Δ 0 , and Δ 6 , which may be partially attributed to alcohols (Table S3), suggests at least that alcohol addition does not exceed consumption of unsaturated hydrocarbons and carbonyls (at Δ 0 , Δ -2 ), and implies that carboxylic addition with C-C fragmentation is a more important reaction pathway for this dataset; this fragmentation may also contribute to the organic mass loss observed if the non-functionalized fragments are volatile. These slopes are similar to gas-phase chamber oxidations of both generated and ambient OA Lambe et al, 2011;Ng et al, 2011).…”

Section: Functionalization-dominant Regime 1: Oxygenated Products Maisupporting

confidence: 64%

Aqueous Secondary Organic Aerosol Formation in Ambient Cloud Water Photo-Oxidations

Schurman

Boris

Desyaterik

et al. 2018

Aerosol Air Qual. Res.

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The current understanding of aqueous secondary organic aerosol (aqSOA) formation is based largely on laboratory investigations of very simple surrogate cloud water solutions that aid mechanistic understanding of aqueous oxidation but may not accurately reflect the influence of the complex ambient matrix present in authentic cloud waters on organic chemistry. In this study, unaltered ambient cloud water and 'biogenically influenced' ambient cloud water (with added pinonic acid) were photo-oxidized, atomized, and dried to simulate the formation of aqSOA in clouds, then analyzed using an Aerodyne Aerosol Mass Spectrometer. Two major chemical regimes were identified: in the first, particle organic mass is gained, then lost; sustained increases in highly oxidized fragments indicate overall organic acid formation, while increases in nominally volatile fragments suggest that evaporation may contribute to the observed mass decrease. In the second regime, the oxidation level of cloud water organic matter decreases as mass decreases, suggesting that oxidized functional groups are fragmented and lost to evaporation. Overall, the rate of aqSOA production in unaltered cloud water decreases as oxygenation increases, until organic mass loss beginning at consistent values of f44 > 0.23 ± 0.05 and O:C > 0.61 ± 0.05. We hypothesize that there may be a parameterizable 'maximum oxidation level' for cloud water above which functional group fragmentation is dominant. These experiments are among the first to quantify organic mass production in ambient cloud water and employ the most atmospherically relevant oxidant concentrations to date.

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“…Laboratory (George and Abbatt, 2010;Poulain et al, 2010;Cappa et al, 2011;Massoli et al, 2010;Lambe et al, 2011;Duplissy et al, 2011;Kuwata et al, 2013;Rickards et al, 2013;Suda et al, 2014) and field studies (Jimenez et al, 2009;Chang et al, 2010;Mei et al, 2013) have demonstrated a robust link between the aerosol oxidation state and the ability of the organic fraction to promote hygroscopic water uptake and CCN activity. Proxies from mass spectrometry such as the fragmentation peak f 44 or the atomic oxygento-carbon ratio are often used to model the increase in hygroscopicity.…”

Section: D Petters Et Al: Prediction Of Cloud Condensation Nuclementioning

confidence: 99%

Prediction of cloud condensation nuclei activity for organic compounds using functional group contribution methods

2016

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Abstract.A wealth of recent laboratory and field experiments demonstrate that organic aerosol composition evolves with time in the atmosphere, leading to changes in the influence of the organic fraction to cloud condensation nuclei (CCN) spectra. There is a need for tools that can realistically represent the evolution of CCN activity to better predict indirect effects of organic aerosol on clouds and climate. This work describes a model to predict the CCN activity of organic compounds from functional group composition. Following previous methods in the literature, we test the ability of semi-empirical group contribution methods in Köh-ler theory to predict the effective hygroscopicity parameter, kappa. However, in our approach we also account for liquidliquid phase boundaries to simulate phase-limited activation behavior. Model evaluation against a selected database of published laboratory measurements demonstrates that kappa can be predicted within a factor of 2. Simulation of homologous series is used to identify the relative effectiveness of different functional groups in increasing the CCN activity of weakly functionalized organic compounds. Hydroxyl, carboxyl, aldehyde, hydroperoxide, carbonyl, and ether moieties promote CCN activity while methylene and nitrate moieties inhibit CCN activity. The model can be incorporated into scale-bridging test beds such as the Generator of Explicit Chemistry and Kinetics of Organics in the Atmosphere (GECKO-A) to evaluate the evolution of kappa for a complex mix of organic compounds and to develop suitable parameterizations of CCN evolution for larger-scale models.

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Laboratory studies of the chemical composition and cloud condensation nuclei (CCN) activity of secondary organic aerosol (SOA) and oxidized primary organic aerosol (OPOA)

Cited by 95 publications

References 71 publications

Chemical aging of single and multicomponent biomass burning aerosol surrogate particles by OH: implications for cloud condensation nucleus activity

Chemical aging of single and multicomponent biomass burning aerosol surrogate particles by OH: implications for cloud condensation nucleus activity

Aqueous Secondary Organic Aerosol Formation in Ambient Cloud Water Photo-Oxidations

Prediction of cloud condensation nuclei activity for organic compounds using functional group contribution methods

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