%APerraud, Véronique%APerraud, Véronique%AHorne, Jeremy%AHorne, Jeremy%AMartinez, Andrew%AMartinez, Andrew%AKalinowski, Jaroslaw%AKalinowski, Jaroslaw%AMeinardi, Simone%AMeinardi, Simone%ADawson, Matthew%ADawson, Matthew%AWingen, Lisa%AWingen, Lisa%ADabdub, Donald%ADabdub, Donald%ABlake, Donald%ABlake, Donald%AGerber, R.%AGerber, R.%AFinlayson-Pitts, Barbara%AFinlayson-Pitts, Barbara%BJournal Name: Proceedings of the National Academy of Sciences; Journal Volume: 112; Journal Issue: 44; Related Information: CHORUS Timestamp: 2019-12-11 10:58:43 %D2015%IProceedings of the National Academy of Sciences %JJournal Name: Proceedings of the National Academy of Sciences; Journal Volume: 112; Journal Issue: 44; Related Information: CHORUS Timestamp: 2019-12-11 10:58:43 %K %MOSTI ID: 10013296 %PMedium: X %TThe future of airborne sulfur-containing particles in the absence of fossil fuel sulfur dioxide emissions %X
Sulfuric acid (H2SO4), formed from oxidation of sulfur dioxide (SO2) emitted during fossil fuel combustion, is a major precursor of new airborne particles, which have well-documented detrimental effects on health, air quality, and climate. Another precursor is methanesulfonic acid (MSA), produced simultaneously with SO2during the atmospheric oxidation of organosulfur compounds (OSCs), such as dimethyl sulfide. In the present work, a multidisciplinary approach is used to examine how contributions of H2SO4and MSA to particle formation will change in a large coastal urban area as anthropogenic fossil fuel emissions of SO2decline. The 3-dimensional University of California Irvine–California Institute of Technology airshed model is used to compare atmospheric concentrations of gas phase MSA, H2SO4, and SO2under current emissions of fossil fuel-associated SO2and a best-case futuristic scenario with zero fossil fuel sulfur emissions. Model additions include results from (