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dc.contributor.authorAlexander, B.
dc.contributor.authorPark, Rokjin J.
dc.contributor.authorJacob, Daniel J.
dc.contributor.authorLi, Q. B.
dc.contributor.authorYantosca, Robert M.
dc.contributor.authorSavarino, J.
dc.contributor.authorLee, C. C. W.
dc.contributor.authorThiemens, M. H.
dc.date.accessioned2010-04-07T14:24:50Z
dc.date.issued2005
dc.identifier.citationAlexander, B., Rokjin J. Park, Daniel J. Jacob, Q.B. Li, Robert M. Yantosca, J. Savarino, C.C.W. Lee, and M.H. Thiemens. 2005. Sulfate formation in sea-salt aerosols: Constraints from oxygen isotopes. Journal of Geophysical Research 110: D10307.en_US
dc.identifier.issn0148-0227en_US
dc.identifier.urihttp://nrs.harvard.edu/urn-3:HUL.InstRepos:3822895
dc.description.abstractWe use observations of the mass-independent oxygen isotopic composition (Δ17O) of sulfate in the marine boundary layer (MBL) to quantify the sulfate source from aqueous SO2 (S(IV)) oxidation by O3 in alkaline sea-salt aerosols. Oxidation by O3 imparts a large Δ17O signature to the resulting sulfate (8.8‰) relative to oxidation by H2O2 (0.9‰) or by OH or O2 (0‰). Ship data from two Indian Ocean Experiment (INDOEX) cruises in the Indian Ocean indicate Δ17O values usually <1‰ in the submicron sulfate aerosol but considerable variability in the supermicron sulfate with frequent occurrences above 1‰ and up to 6.7‰. The large Δ17O values are associated with high concentrations of sea-salt aerosols, providing evidence for the S(IV) + O3 pathway. We use a global chemical transport model (GEOS-CHEM) to interpret quantitatively the INDOEX observations and to assess the global importance of sulfate production in sea-salt aerosols. The model accounts for titration of sea-salt alkalinity in the MBL by uptake of acid gases (SO2, H2SO4, and HNO3), shutting down the S(IV) + O3 pathway. We find that this titration occurs rapidly over much of the oceans except at high latitudes (strong sea-salt emission) and is due to both the S(IV) + O3 reaction and HNO3 (g) condensation; that is, sulfate formation in sea-salt aerosols is limited by the alkalinity flux from the ocean and by competition for this alkalinity supply from HNO3 (g). The model is consistent with the Δ17O magnitudes and patterns in the INDOEX data. Titration of alkalinity is critical for the success of the model simulation. Regeneration of sea-salt aerosol alkalinity by OH uptake is inconsistent with the Δ17O observations in INDOEX. Model results indicate that sulfate production in sea-salt aerosols decreases MBL SO2 concentrations and gas phase H2SO4 production rates by typically 10–30% (up to >70%) and increases MBL sulfate concentrations by typically >10% (up to 30%). Globally, this mechanism contributes 9% of atmospheric sulfate production and 1% of the sulfate burden. The impact on H2SO4 (g) formation and implications for the potential formation of new particles in the MBL warrants inclusion in models examining the radiative effects of sulfate aerosols.en_US
dc.description.sponsorshipEarth and Planetary Sciencesen_US
dc.description.sponsorshipEngineering and Applied Sciencesen_US
dc.language.isoen_USen_US
dc.publisherAmerican Geophysical Unionen_US
dc.relation.isversionofdoi:10.1029/2004JD005659en_US
dash.licenseLAA
dc.titleSulfate Formation in Sea-Salt Aerosols: Constraints from Oxygen Isotopesen_US
dc.typeJournal Articleen_US
dc.description.versionVersion of Recorden_US
dc.relation.journalJournal of Geophysical Research -All Series-en_US
dash.depositing.authorJacob, Daniel J.
dc.date.available2010-04-07T14:24:50Z
dc.identifier.doi10.1029/2004JD005659*
dash.contributor.affiliatedYantosca, Robert
dash.contributor.affiliatedJacob, Daniel


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