Product distribution, kinetics, and aerosol formation from the OH oxidation of dimethyl sulfide under different RO 2 regimes

The atmospheric oxidation of dimethyl sulfide (DMS) represents a major natural source of atmospheric sulfate aerosols. However, there remain large uncertainties in our understanding of the underlying chemistry that governs the product distribution and sulfate yield from DMS oxidation. Here, chamber...

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Veröffentlicht in:	Atmospheric chemistry and physics 2022-12, Vol.22 (24), p.16003-16015
Hauptverfasser:	Ye, Qing, Goss, Matthew B., Krechmer, Jordan E., Majluf, Francesca, Zaytsev, Alexander, Li, Yaowei, Roscioli, Joseph R., Canagaratna, Manjula, Keutsch, Frank N., Heald, Colette L., Kroll, Jesse H.
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creator	Ye, Qing Goss, Matthew B. Krechmer, Jordan E. Majluf, Francesca Zaytsev, Alexander Li, Yaowei Roscioli, Joseph R. Canagaratna, Manjula Keutsch, Frank N. Heald, Colette L. Kroll, Jesse H.
description	The atmospheric oxidation of dimethyl sulfide (DMS) represents a major natural source of atmospheric sulfate aerosols. However, there remain large uncertainties in our understanding of the underlying chemistry that governs the product distribution and sulfate yield from DMS oxidation. Here, chamber experiments were conducted to simulate gas-phase OH-initiated oxidation of DMS under a range of reaction conditions. Most importantly, the bimolecular lifetime (τbi) of the peroxy radical CH3SCH2OO was varied over several orders of magnitude, enabling the examination of the role of peroxy radical isomerization reactions on product formation. An array of analytical instruments was used to measure nearly all sulfur-containing species in the reaction mixture, and results were compared with a near-explicit chemical mechanism. When relative humidity was low, “sulfur closure” was achieved under both high-NO (τbi10 s) conditions, though product distributions were substantially different in the two cases. Under high-NO conditions, approximately half the product sulfur was in the particle phase, as methane sulfonic acid (MSA) and sulfate, with most of the remainder as SO2 (which in the atmosphere would eventually oxidize to sulfate or be lost to deposition). Under low-NO conditions, hydroperoxymethyl thioformate (HPMTF, HOOCH2SCHO), formed from CH3SCH2OO isomerization, dominates the sulfur budget over the course of the experiment, suppressing or delaying the formation of SO2 and particulate matter. The isomerization rate constant of CH3SCH2OO at 295 K is found to be 0.13±0.03 s−1, in broad agreement with other recent laboratory measurements. The rate constants for the OH oxidation of key first-generation oxidation products (HPMTF and methyl thioformate, MTF) were also determined (kOH+HPMTF=2.1×10-11 cm3 molec.−1 s−1, kOH+MTF=1.35×10-11 cm3 molec.−1 s−1). Product measurements agree reasonably well with mechanistic predictions in terms of total sulfur distribution and concentrations of most individual species, though the mechanism overpredicts sulfate and underpredicts MSA under high-NO conditions. Lastly, results from high-relative-humidity conditions suggest efficient heterogenous loss of at least some gas-phase products.
doi_str_mv	10.5194/acp-22-16003-2022
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However, there remain large uncertainties in our understanding of the underlying chemistry that governs the product distribution and sulfate yield from DMS oxidation. Here, chamber experiments were conducted to simulate gas-phase OH-initiated oxidation of DMS under a range of reaction conditions. Most importantly, the bimolecular lifetime (τbi) of the peroxy radical CH3SCH2OO was varied over several orders of magnitude, enabling the examination of the role of peroxy radical isomerization reactions on product formation. An array of analytical instruments was used to measure nearly all sulfur-containing species in the reaction mixture, and results were compared with a near-explicit chemical mechanism. When relative humidity was low, “sulfur closure” was achieved under both high-NO (τbi<0.1 s) and low-NO (τbi>10 s) conditions, though product distributions were substantially different in the two cases. Under high-NO conditions, approximately half the product sulfur was in the particle phase, as methane sulfonic acid (MSA) and sulfate, with most of the remainder as SO2 (which in the atmosphere would eventually oxidize to sulfate or be lost to deposition). Under low-NO conditions, hydroperoxymethyl thioformate (HPMTF, HOOCH2SCHO), formed from CH3SCH2OO isomerization, dominates the sulfur budget over the course of the experiment, suppressing or delaying the formation of SO2 and particulate matter. The isomerization rate constant of CH3SCH2OO at 295 K is found to be 0.13±0.03 s−1, in broad agreement with other recent laboratory measurements. The rate constants for the OH oxidation of key first-generation oxidation products (HPMTF and methyl thioformate, MTF) were also determined (kOH+HPMTF=2.1×10-11 cm3 molec.−1 s−1, kOH+MTF=1.35×10-11 cm3 molec.−1 s−1). Product measurements agree reasonably well with mechanistic predictions in terms of total sulfur distribution and concentrations of most individual species, though the mechanism overpredicts sulfate and underpredicts MSA under high-NO conditions. 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However, there remain large uncertainties in our understanding of the underlying chemistry that governs the product distribution and sulfate yield from DMS oxidation. Here, chamber experiments were conducted to simulate gas-phase OH-initiated oxidation of DMS under a range of reaction conditions. Most importantly, the bimolecular lifetime (τbi) of the peroxy radical CH3SCH2OO was varied over several orders of magnitude, enabling the examination of the role of peroxy radical isomerization reactions on product formation. An array of analytical instruments was used to measure nearly all sulfur-containing species in the reaction mixture, and results were compared with a near-explicit chemical mechanism. When relative humidity was low, “sulfur closure” was achieved under both high-NO (τbi<0.1 s) and low-NO (τbi>10 s) conditions, though product distributions were substantially different in the two cases. Under high-NO conditions, approximately half the product sulfur was in the particle phase, as methane sulfonic acid (MSA) and sulfate, with most of the remainder as SO2 (which in the atmosphere would eventually oxidize to sulfate or be lost to deposition). Under low-NO conditions, hydroperoxymethyl thioformate (HPMTF, HOOCH2SCHO), formed from CH3SCH2OO isomerization, dominates the sulfur budget over the course of the experiment, suppressing or delaying the formation of SO2 and particulate matter. The isomerization rate constant of CH3SCH2OO at 295 K is found to be 0.13±0.03 s−1, in broad agreement with other recent laboratory measurements. The rate constants for the OH oxidation of key first-generation oxidation products (HPMTF and methyl thioformate, MTF) were also determined (kOH+HPMTF=2.1×10-11 cm3 molec.−1 s−1, kOH+MTF=1.35×10-11 cm3 molec.−1 s−1). Product measurements agree reasonably well with mechanistic predictions in terms of total sulfur distribution and concentrations of most individual species, though the mechanism overpredicts sulfate and underpredicts MSA under high-NO conditions. Lastly, results from high-relative-humidity conditions suggest efficient heterogenous loss of at least some gas-phase products.</description><issn>1680-7324</issn><issn>1680-7324</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2022</creationdate><recordtype>article</recordtype><recordid>eNpNkE1LAzEURYMoWKs_wF1w3dF8TGaapRRthUJFdB0yyYuNzkxKkgEL_nin1oWrd7kcLryD0DUlt4LK8k6bXcFYQStCeMEIYydoQqs5KWrOytN_-RxdpPRBCBOElhP0_RyDHUzG1qccfTNkH_oZ_vQ9ZG_SDOveYg0xpNBiF2KnDwB2MXQ4bwFvVjh8eXtsgxtnOsjbfYvT0DpvAQ-9hTjWzkGEPuOXDWY4wvvIpUt05nSb4OrvTtHb48PrYlWsN8unxf26MJTWtBBzK1jJRK1rR0rjtKyhqRrNSlmBNc1YO0lqDcZQmEvGtTVcNpxQUYF0lk_RzXE3pOxVMj6D2ZrQ92CyopIISegI0SNkxmdTBKd20Xc67hUl6uBYjY4VY-rXsTo45j9rvHH-</recordid><startdate>20221220</startdate><enddate>20221220</enddate><creator>Ye, Qing</creator><creator>Goss, Matthew B.</creator><creator>Krechmer, Jordan E.</creator><creator>Majluf, Francesca</creator><creator>Zaytsev, Alexander</creator><creator>Li, Yaowei</creator><creator>Roscioli, Joseph R.</creator><creator>Canagaratna, Manjula</creator><creator>Keutsch, Frank N.</creator><creator>Heald, Colette L.</creator><creator>Kroll, Jesse H.</creator><general>Copernicus GmbH</general><scope>AAYXX</scope><scope>CITATION</scope><scope>OTOTI</scope><orcidid>https://orcid.org/0000-0003-2894-5738</orcidid><orcidid>https://orcid.org/0000-0002-6275-521X</orcidid><orcidid>https://orcid.org/0000-0003-0725-6108</orcidid><orcidid>https://orcid.org/0000-0003-3797-8988</orcidid><orcidid>https://orcid.org/0000-0003-3642-0659</orcidid><orcidid>https://orcid.org/000000026275521X</orcidid><orcidid>https://orcid.org/0000000336420659</orcidid><orcidid>https://orcid.org/0000000307256108</orcidid><orcidid>https://orcid.org/0000000337978988</orcidid><orcidid>https://orcid.org/0000000328945738</orcidid></search><sort><creationdate>20221220</creationdate><title>Product distribution, kinetics, and aerosol formation from the OH oxidation of dimethyl sulfide under different RO 2 regimes</title><author>Ye, Qing ; Goss, Matthew B. ; Krechmer, Jordan E. ; Majluf, Francesca ; Zaytsev, Alexander ; Li, Yaowei ; Roscioli, Joseph R. ; Canagaratna, Manjula ; Keutsch, Frank N. ; Heald, Colette L. ; Kroll, Jesse H.</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c1171-58d524257a7f04cfa97eb6ba2496edcba7ff907aecc1e8923adc39b30156e9fd3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2022</creationdate><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Ye, Qing</creatorcontrib><creatorcontrib>Goss, Matthew B.</creatorcontrib><creatorcontrib>Krechmer, Jordan E.</creatorcontrib><creatorcontrib>Majluf, Francesca</creatorcontrib><creatorcontrib>Zaytsev, Alexander</creatorcontrib><creatorcontrib>Li, Yaowei</creatorcontrib><creatorcontrib>Roscioli, Joseph R.</creatorcontrib><creatorcontrib>Canagaratna, Manjula</creatorcontrib><creatorcontrib>Keutsch, Frank N.</creatorcontrib><creatorcontrib>Heald, Colette L.</creatorcontrib><creatorcontrib>Kroll, Jesse H.</creatorcontrib><collection>CrossRef</collection><collection>OSTI.GOV</collection><jtitle>Atmospheric chemistry and physics</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Ye, Qing</au><au>Goss, Matthew B.</au><au>Krechmer, Jordan E.</au><au>Majluf, Francesca</au><au>Zaytsev, Alexander</au><au>Li, Yaowei</au><au>Roscioli, Joseph R.</au><au>Canagaratna, Manjula</au><au>Keutsch, Frank N.</au><au>Heald, Colette L.</au><au>Kroll, Jesse H.</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Product distribution, kinetics, and aerosol formation from the OH oxidation of dimethyl sulfide under different RO 2 regimes</atitle><jtitle>Atmospheric chemistry and physics</jtitle><date>2022-12-20</date><risdate>2022</risdate><volume>22</volume><issue>24</issue><spage>16003</spage><epage>16015</epage><pages>16003-16015</pages><issn>1680-7324</issn><eissn>1680-7324</eissn><abstract>The atmospheric oxidation of dimethyl sulfide (DMS) represents a major natural source of atmospheric sulfate aerosols. However, there remain large uncertainties in our understanding of the underlying chemistry that governs the product distribution and sulfate yield from DMS oxidation. Here, chamber experiments were conducted to simulate gas-phase OH-initiated oxidation of DMS under a range of reaction conditions. Most importantly, the bimolecular lifetime (τbi) of the peroxy radical CH3SCH2OO was varied over several orders of magnitude, enabling the examination of the role of peroxy radical isomerization reactions on product formation. An array of analytical instruments was used to measure nearly all sulfur-containing species in the reaction mixture, and results were compared with a near-explicit chemical mechanism. When relative humidity was low, “sulfur closure” was achieved under both high-NO (τbi<0.1 s) and low-NO (τbi>10 s) conditions, though product distributions were substantially different in the two cases. Under high-NO conditions, approximately half the product sulfur was in the particle phase, as methane sulfonic acid (MSA) and sulfate, with most of the remainder as SO2 (which in the atmosphere would eventually oxidize to sulfate or be lost to deposition). Under low-NO conditions, hydroperoxymethyl thioformate (HPMTF, HOOCH2SCHO), formed from CH3SCH2OO isomerization, dominates the sulfur budget over the course of the experiment, suppressing or delaying the formation of SO2 and particulate matter. The isomerization rate constant of CH3SCH2OO at 295 K is found to be 0.13±0.03 s−1, in broad agreement with other recent laboratory measurements. The rate constants for the OH oxidation of key first-generation oxidation products (HPMTF and methyl thioformate, MTF) were also determined (kOH+HPMTF=2.1×10-11 cm3 molec.−1 s−1, kOH+MTF=1.35×10-11 cm3 molec.−1 s−1). Product measurements agree reasonably well with mechanistic predictions in terms of total sulfur distribution and concentrations of most individual species, though the mechanism overpredicts sulfate and underpredicts MSA under high-NO conditions. 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title	Product distribution, kinetics, and aerosol formation from the OH oxidation of dimethyl sulfide under different RO 2 regimes
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