Oxidation of SO&amp;lt;sub&amp;gt;2&amp;lt;/sub&amp;gt; by stabilized Criegee intermediate (sCI) radicals as a crucial source for atmospheric sulfuric acid concentrations

Boy, Michael; Mogensen, D.; Smolander, Sampo; Zhou, Luxi; Nieminen, Tuomo; Paasonen, Pauli; Plaß-Dülmer, C.; Sipilä, Mikko; Petäj̈ä, Tuukka; Mauldin, L.; Berresheim, H.; Kulmala, Markku

doi:10.5194/acp-13-3865-2013

Cited by 141 publications

(160 citation statements)

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“…Sulfuric acid plays a key role in Earth's atmosphere, triggering secondary aerosol formation (Kulmala et al, 2004;Berndt et al, 2005, Riipinen et al, 2007Sipilä et al, 2010;Kerminen et al, 2010), and thus connects natural and anthropogenic SO 2 emissions to global climate via indirect aerosol effects on radiative forcing. The effect of sCI on SO 2 oxidation was assessed by Boy et al (2013), who simulated sulfuric acid production at the SMEAR (Station for measuring atmosphere-ecosystem relations) II boreal forest field station using the reaction rate coefficients suggested by Mauldin III et al (2012). Their results supported the experimental observations by Mauldin III et al (2012), showing that a signif-icant fraction (several tens of percents) of ground-level gas phase sulfuric acid originates probably from sCI-initiated oxidation of SO 2 .…”

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confidence: 72%

Reactivity of stabilized Criegee intermediates (sCIs) from isoprene and monoterpene ozonolysis toward SO<sub>2</sub> and organic acids

et al. 2014

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Abstract. Oxidation processes in Earth's atmosphere are tightly connected to many environmental and human health issues and are essential drivers for biogeochemistry. Until the recent discovery of the atmospheric relevance of the reaction of stabilized Criegee intermediates (sCIs) with SO 2 , atmospheric oxidation processes were thought to be dominated by a few main oxidants: ozone, hydroxyl radicals (OH), nitrate radicals and, e.g. over oceans, halogen atoms such as chlorine. Here, we report results from laboratory experiments at 293 K and atmospheric pressure focusing on sCI formation from the ozonolysis of isoprene and the most abundant monoterpenes (α-pinene and limonene), and subsequent reactions of the resulting sCIs with SO 2 producing sulfuric acid (H 2 SO 4 ). The measured total sCI yields were (0.15 ± 0.07), (0.27 ± 0.12) and (0.58 ± 0.26) for α-pinene, limonene and isoprene, respectively. The ratio between the rate coefficient for the sCI loss (including thermal decomposition and the reaction with water vapour) and the rate coefficient for the reaction of sCI with SO 2 , k(loss) / k(sCI + SO 2 ), was determined at relative humidities of 10 and 50 %. Observed values represent the average reactivity of all sCIs produced from the individual alkene used in the ozonolysis. For the monoterpene-derived sCIs, the relative rate coefficients k(loss) / k(sCI + SO 2 ) were in the range (2.0-2.4) × 10 12 molecules cm −3 and nearly independent of the relative humidity. This fact points to a minor importance of the sCI + H 2 O reaction in the case of the sCI arising from α-pinene and limonene. For the isoprene sCIs, however, the ratio k(loss) / k(sCI + SO 2 ) was strongly dependent on the relative humidity. To explore whether sCIs could have a more general role in atmospheric oxidation, we investigated as an example the reactivity of acetone oxide (sCI from the ozonolysis of 2,3-dimethyl-2-butene) toward small organic acids, i.e. formic and acetic acid. Acetone oxide was found to react faster with the organic acids than with SO 2 ; k(sCI + acid) / k(sCI + SO 2 ) = (2.8 ± 0.3) for formic acid, and k(sCI + acid) / k(sCI + SO 2 ) = (3.4 ± 0.2) for acetic acid. This finding indicates that sCIs can play a role in the formation and loss of other atmospheric constituents besides SO 2 .

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Reactivity of stabilized Criegee intermediates (sCIs) from isoprene and monoterpene ozonolysis toward SO<sub>2</sub> and organic acids

et al. 2014

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“…Recent studies show that SO 2 reacts much faster with Criegee radicals than previously reported (10 −13 -10 −11 cm 3 s −1 ; Welz et al, 2012;Mauldin III et al, 2012;Boy et al, 2013). The differences in the experiments with and without SO 2 could be explained by reaction of a precursor Criegee radical with that species, hindering the formation of these acids.…”

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confidence: 42%

Online measurements of water-soluble organic acids in the gas and aerosol phase from the photooxidation of 1,3,5-trimethylbenzene

et al. 2014

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Abstract. The formation of organic acids during photooxidation of 1,3,5-trimethylbenzene (TMB) in the presence of NO x was investigated with an online ion chromatography (IC) instrument coupled to a mass spectrometer (MS) at the Paul Scherrer Institute's smog chamber. Gas and aerosol phase were both sampled. Molecular formulas were attributed to 12 compounds with the help of high-resolution MS data from filter extracts (two compounds in the gas phase only, two in the aerosol phase only and eight in both). Seven of those species could be identified: formic acid, acetic acid, glycolic acid, butanoic acid, pyruvic acid, lactic acid and methylmaleic acid. While the organic acid fraction present in the aerosol phase does not strongly depend on the precursor concentration (6 to 20 %), the presence of SO 2 reduces this amount to less than 3 % for both high and low precursor concentration scenarios. A large amount of acetic acid was injected during one experiment after aerosol formation, but no increase of acetic acid particle concentration could be observed. This indicates that the unexpected presence of volatile organic acids in the particle phase might not be due to partitioning effects, but to reactive uptake or to sampling artefact.

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“…Now it is generally accepted that ozonolysis of alkenes proceeds via Criegee intermediates, highly reactive species postulated in 1949 by Rudolf Criegee. 1,2 In the troposphere, Criegee intermediates are involved in several important atmospheric reactions, 3 including reactions with SO 2 and NO 2 , [4][5][6][7] or can be photolyzed by near UV light, [7][8][9][10] as shown for CH 2 The formation of SO 3 and NO 3 , as in (R2) and (R3), plays an important role in atmospheric chemistry, 11,12 including aerosol and cloud formation. The formation of O( 1 D), as in (R4), will result in OH formation through (R5).…”

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The UV absorption spectrum of the simplest Criegee intermediate CH₂OO

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SO 2 scavenging and self-reaction of CH 2 OO were utilized for the decay of CH 2 OO to extract the absorption spectrum of CH 2 OO under bulk conditions. Absolute absorption cross sections of CH 2 OO at 308.4 and 351.8 nm were obtained from laser-depletion measurements in a jet-cooled molecular beam. The peak cross section is (1.23 AE 0.18) Â 10 À17 cm 2 at 340 nm.Ozonolysis is a major removal mechanism in the troposphere for unsaturated hydrocarbons which are emitted in large quantities from both natural and human sources. Now it is generally accepted that ozonolysis of alkenes proceeds via Criegee intermediates, highly reactive species postulated in 1949 by Rudolf Criegee. 1,2 In the troposphere, Criegee intermediates are involved in several important atmospheric reactions, 3 including reactions with SO 2 and NO 2 , 4-7 or can be photolyzed by near UV light, 7-10 as shown for CH 2 OO in (R1)-(R4).The formation of SO 3 and NO 3 , as in (R2) and (R3), plays an important role in atmospheric chemistry, 11,12 including aerosol and cloud formation. The formation of O( 1 D), as in (R4), will result in OH formation through (R5).Because CH 2 OO absorbs strongly at wavelengths longer than 300 nm, 7-9 tropospheric photolysis of CH 2 OO would be quite efficient with an effective photolysis lifetime on the order of 1 second. 8 As a result, the OH formation of (R4) + (R5) may contribute significantly to the atmospheric OH concentrations.Despite their importance, the direct detection of Criegee intermediates was not realized until recently. 4,13 Welz et al. 4 reported an efficient way to prepare Criegee intermediates. For example, CH 2 OO can be prepared via (R6) + (R7a). Welz et al. 4 also demonstrated the direct detection of CH 2 OO by using vacuum UV photoionization mass spectrometry. The parent ion CH 2 O 2 + was observed when the photon energy exceeded the ionization energy of CH 2 OO (10.0 eV); other isomers like dioxirane and formic acid were excluded due to their different ionization energies. 4 At low pressure, the yield of (R7a) is close to unity, 14,15 while the adduct formation (R7b) may dominate at near atmospheric pressures. 14The kinetics of CH 2 OO reactions with SO 2 and NO 2 were investigated by Welz et al. 4 and by Stone et al. 5 by observing the disappearance of CH 2 OO and by detecting the H 2 CO products, respectively. The rate coefficients of these reactions were found to be unexpectedly rapid and imply a substantially greater role of Criegee intermediates in models of tropospheric sulfate and nitrate chemistry.Beames et al. 8 recorded the UV spectrum of CH 2 OO through observing its depletion in a molecular beam upon laser irradiation (an action spectrum). Based on their laser pulse energy and spot size, Beames et al. 8 roughly estimated the peak absorption cross section to be 5 Â 10 À17 cm 2 (at 335 nm with FWHM B40 nm). Lehman et al. 10 measured the angular and velocity distributions of the O( 1 D) photoproduct arising from UV excitation of CH 2 OO in the 300-365 nm range. From the observed

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Oxidation of SO<sub>2</sub> by stabilized Criegee intermediate (sCI) radicals as a crucial source for atmospheric sulfuric acid concentrations

Cited by 141 publications

References 61 publications

Reactivity of stabilized Criegee intermediates (sCIs) from isoprene and monoterpene ozonolysis toward SO<sub>2</sub> and organic acids

Reactivity of stabilized Criegee intermediates (sCIs) from isoprene and monoterpene ozonolysis toward SO<sub>2</sub> and organic acids

Online measurements of water-soluble organic acids in the gas and aerosol phase from the photooxidation of 1,3,5-trimethylbenzene

The UV absorption spectrum of the simplest Criegee intermediate CH₂OO

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Oxidation of SO&lt;sub&gt;2&lt;/sub&gt; by stabilized Criegee intermediate (sCI) radicals as a crucial source for atmospheric sulfuric acid concentrations

Cited by 141 publications

References 61 publications

Reactivity of stabilized Criegee intermediates (sCIs) from isoprene and monoterpene ozonolysis toward SO&lt;sub&gt;2&lt;/sub&gt; and organic acids

Reactivity of stabilized Criegee intermediates (sCIs) from isoprene and monoterpene ozonolysis toward SO&lt;sub&gt;2&lt;/sub&gt; and organic acids

Online measurements of water-soluble organic acids in the gas and aerosol phase from the photooxidation of 1,3,5-trimethylbenzene

The UV absorption spectrum of the simplest Criegee intermediate CH2OO

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Oxidation of SO<sub>2</sub> by stabilized Criegee intermediate (sCI) radicals as a crucial source for atmospheric sulfuric acid concentrations

Reactivity of stabilized Criegee intermediates (sCIs) from isoprene and monoterpene ozonolysis toward SO<sub>2</sub> and organic acids

Reactivity of stabilized Criegee intermediates (sCIs) from isoprene and monoterpene ozonolysis toward SO<sub>2</sub> and organic acids

The UV absorption spectrum of the simplest Criegee intermediate CH₂OO