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dc.contributor.authorSorooshian, Armin
dc.contributor.authorShingler, T.
dc.contributor.authorCrosbie, E.
dc.contributor.authorBarth, M. C.
dc.contributor.authorHomeyer, C. R.
dc.contributor.authorCampuzano-Jost, P.
dc.contributor.authorDay, D. A.
dc.contributor.authorJimenez, J. L.
dc.contributor.authorThornhill, K. L.
dc.contributor.authorZiemba, L. D.
dc.contributor.authorBlake, D. R.
dc.contributor.authorFried, A.
dc.date.accessioned2017-06-23T19:45:28Z
dc.date.available2017-06-23T19:45:28Z
dc.date.issued2017-04-27
dc.identifier.citationContrasting aerosol refractive index and hygroscopicity in the inflow and outflow of deep convective storms: Analysis of airborne data from DC3 2017, 122 (8):4565 Journal of Geophysical Research: Atmospheresen
dc.identifier.issn2169897X
dc.identifier.doi10.1002/2017JD026638
dc.identifier.urihttp://hdl.handle.net/10150/624344
dc.description.abstractWe examine three case studies during the Deep Convective Clouds and Chemistry (DC3) field experiment when storm inflow and outflow air were sampled for aerosol subsaturated hygroscopicity and the real part of refractive index (n) with a Differential Aerosol Sizing and Hygroscopicity Probe (DASH-SP) on the NASA DC-8. Relative to inflow aerosol particles, outflow particles were more hygroscopic (by 0.03 based on the estimated parameter) in one of the three storms examined. Two of three control flights with no storm convection reveal higher values, albeit by only 0.02, at high altitude (> 8km) versus < 4km. Entrainment modeling shows that measured values in the outflow of the three storm flights are higher than predicted values (by 0.03-0.11) based on knowledge of values from the inflow and clear air adjacent to the storms. This suggests that other process(es) contributed to hygroscopicity enhancements such as secondary aerosol formation via aqueous-phase chemistry. Values of n were higher in the outflow of two of the three storm flights, reaching as high as 1.54. More statistically significant differences were observed in control flights (no storms) where n decreased from 1.50-1.52 (< 4km) to 1.49-1.50 (> 8km). Chemical data show that enhanced hygroscopicity was coincident with lower organic mass fractions, higher sulfate mass fractions, and higher O:C ratios of organic aerosol. Refractive index did not correlate as well with available chemical data. Deep convection is shown to alter aerosol radiative properties, which has implications for aerosol effects on climate.
dc.description.sponsorshipNASA [NNX12AC1OG, NNX14AP75G, NNX12AC03G, NNX15AT96G]; NASA Earth and Space Science Fellowship [NNX14AK79H]; ONR [N00014-10-1-0811, N00014-16-1-2567]; National Science Foundation [AGS-1522910]; National Science Foundationen
dc.language.isoenen
dc.publisherAMER GEOPHYSICAL UNIONen
dc.relation.urlhttp://doi.wiley.com/10.1002/2017JD026638en
dc.rights© 2017. American Geophysical Union. All Rights Reserved.en
dc.rights.urihttp://rightsstatements.org/vocab/InC/1.0/
dc.subjectDC3en
dc.subjectaerosolen
dc.subjecthygroscopicityen
dc.subjectrefractive indexen
dc.subjectentrainmenten
dc.subjectcloud processingen
dc.titleContrasting aerosol refractive index and hygroscopicity in the inflow and outflow of deep convective storms: Analysis of airborne data from DC3en
dc.typeArticleen
dc.contributor.departmentUniv Arizona, Dept Chem & Environm Engnen
dc.contributor.departmentUniv Arizona, Dept Hydrol & Atmospher Scien
dc.identifier.journalJournal of Geophysical Research: Atmospheresen
dc.description.note6 month embargo; First published: 27 April 2017en
dc.description.collectioninformationThis item from the UA Faculty Publications collection is made available by the University of Arizona with support from the University of Arizona Libraries. If you have questions, please contact us at repository@u.library.arizona.edu.en
dc.eprint.versionFinal published versionen
dc.contributor.institutionDepartment of Chemical and Environmental Engineering; University of Arizona; Tucson Arizona USA
dc.contributor.institutionChemistry and Dynamics Branch; National Aeronautics and Space Administration Langley Research Center; Hampton Virginia USA
dc.contributor.institutionChemistry and Dynamics Branch; National Aeronautics and Space Administration Langley Research Center; Hampton Virginia USA
dc.contributor.institutionNational Center for Atmospheric Research; Boulder Colorado USA
dc.contributor.institutionSchool of Meteorology; University of Oklahoma; Norman Oklahoma USA
dc.contributor.institutionCooperative Institute for Research in Environmental Sciences and Department of Chemistry and Biochemistry; University of Colorado Boulder; Boulder Colorado USA
dc.contributor.institutionCooperative Institute for Research in Environmental Sciences and Department of Chemistry and Biochemistry; University of Colorado Boulder; Boulder Colorado USA
dc.contributor.institutionCooperative Institute for Research in Environmental Sciences and Department of Chemistry and Biochemistry; University of Colorado Boulder; Boulder Colorado USA
dc.contributor.institutionChemistry and Dynamics Branch; National Aeronautics and Space Administration Langley Research Center; Hampton Virginia USA
dc.contributor.institutionChemistry and Dynamics Branch; National Aeronautics and Space Administration Langley Research Center; Hampton Virginia USA
dc.contributor.institutionDepartment of Chemistry; University of California; Irvine California USA
dc.contributor.institutionInstitute of Arctic and Alpine Research; University of Colorado Boulder; Boulder Colorado USA
refterms.dateFOA2017-10-28T00:00:00Z
html.description.abstractWe examine three case studies during the Deep Convective Clouds and Chemistry (DC3) field experiment when storm inflow and outflow air were sampled for aerosol subsaturated hygroscopicity and the real part of refractive index (n) with a Differential Aerosol Sizing and Hygroscopicity Probe (DASH-SP) on the NASA DC-8. Relative to inflow aerosol particles, outflow particles were more hygroscopic (by 0.03 based on the estimated parameter) in one of the three storms examined. Two of three control flights with no storm convection reveal higher values, albeit by only 0.02, at high altitude (> 8km) versus < 4km. Entrainment modeling shows that measured values in the outflow of the three storm flights are higher than predicted values (by 0.03-0.11) based on knowledge of values from the inflow and clear air adjacent to the storms. This suggests that other process(es) contributed to hygroscopicity enhancements such as secondary aerosol formation via aqueous-phase chemistry. Values of n were higher in the outflow of two of the three storm flights, reaching as high as 1.54. More statistically significant differences were observed in control flights (no storms) where n decreased from 1.50-1.52 (< 4km) to 1.49-1.50 (> 8km). Chemical data show that enhanced hygroscopicity was coincident with lower organic mass fractions, higher sulfate mass fractions, and higher O:C ratios of organic aerosol. Refractive index did not correlate as well with available chemical data. Deep convection is shown to alter aerosol radiative properties, which has implications for aerosol effects on climate.


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