Snowpack processing of acetaldehyde and acetone in the Arctic atmospheric boundary layer

Acetaldehyde (CH 3CHO) and acetone (CH 3C(O)CH 3) concentrations in ambient air, in snowpack air, and bulk snow were determined at Alert, Nunavut, Canada, as a part of the Polar Sunrise Experiment (PSE): ALERT 2000. During the period of continuous sunlight, vertical profiles of ambient and snowpack...

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Veröffentlicht in:	Atmospheric environment (1994) 2002-05, Vol.36 (15), p.2743-2752
Hauptverfasser:	Guimbaud, Christophe, Grannas, Amanda M, Shepson, Paul B, Fuentes, José D, Boudries, Hacene, Bottenheim, Jan W, Dominé, Florent, Houdier, Stephan, Perrier, Sébastien, Biesenthal, Thomas B, Splawn, Bryan G
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Sprache:	eng
Schlagworte:	Acetaldehyde Acetone Arctic chemistry Polar Sunrise Experiment 2000 Snowpack
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container_end_page	2752
container_issue	15
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container_title	Atmospheric environment (1994)
container_volume	36
creator	Guimbaud, Christophe Grannas, Amanda M Shepson, Paul B Fuentes, José D Boudries, Hacene Bottenheim, Jan W Dominé, Florent Houdier, Stephan Perrier, Sébastien Biesenthal, Thomas B Splawn, Bryan G
description	Acetaldehyde (CH 3CHO) and acetone (CH 3C(O)CH 3) concentrations in ambient air, in snowpack air, and bulk snow were determined at Alert, Nunavut, Canada, as a part of the Polar Sunrise Experiment (PSE): ALERT 2000. During the period of continuous sunlight, vertical profiles of ambient and snowpack air exhibited large concentration gradients through the top ∼10 cm of the snowpack, implying a flux of carbonyl compounds from the surface to the atmosphere. From vertical profile and eddy diffusivity measurements made simultaneously on 22 April, acetaldehyde and acetone fluxes of 4.2(±2.1)×10 8 and 6.2(±4.2)×10 8 molecules cm −2 s −1 were derived, respectively. For this day, the sources and sinks of CH 3CHO from gas phase chemistry were estimated. The result showed that the snowpack flux of CH 3CHO to the atmosphere was as large as the calculated CH 3CHO loss rate from known atmospheric gas phase reactions, and at least 40 times larger (in the surface layer) than the volumetric rate of acetaldehyde produced from the assumed main atmospheric gas phase reaction, i.e. reaction of ethane with hydroxyl radicals. In addition, acetaldehyde bulk snow phase measurements showed that acetaldehyde was produced in or on the snow phase, likely from a photochemical origin. The time series for the observed CH 3C(O)CH 3, ozone (O 3), and propane during PSE 1995, PSE 1998, and ALERT 2000 showed a consistent anti-correlation between acetone and O 3 and between acetone and propane. However, our data and model simulations showed that the acetone increase during ozone depletion events cannot be explained by gas phase chemistry involving propane oxidation. These results suggest that the snowpack is a significant source of acetaldehyde and acetone to the Arctic boundary layer.
doi_str_mv	10.1016/S1352-2310(02)00107-3
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During the period of continuous sunlight, vertical profiles of ambient and snowpack air exhibited large concentration gradients through the top ∼10 cm of the snowpack, implying a flux of carbonyl compounds from the surface to the atmosphere. From vertical profile and eddy diffusivity measurements made simultaneously on 22 April, acetaldehyde and acetone fluxes of 4.2(±2.1)×10 8 and 6.2(±4.2)×10 8 molecules cm −2 s −1 were derived, respectively. For this day, the sources and sinks of CH 3CHO from gas phase chemistry were estimated. The result showed that the snowpack flux of CH 3CHO to the atmosphere was as large as the calculated CH 3CHO loss rate from known atmospheric gas phase reactions, and at least 40 times larger (in the surface layer) than the volumetric rate of acetaldehyde produced from the assumed main atmospheric gas phase reaction, i.e. reaction of ethane with hydroxyl radicals. In addition, acetaldehyde bulk snow phase measurements showed that acetaldehyde was produced in or on the snow phase, likely from a photochemical origin. The time series for the observed CH 3C(O)CH 3, ozone (O 3), and propane during PSE 1995, PSE 1998, and ALERT 2000 showed a consistent anti-correlation between acetone and O 3 and between acetone and propane. However, our data and model simulations showed that the acetone increase during ozone depletion events cannot be explained by gas phase chemistry involving propane oxidation. 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During the period of continuous sunlight, vertical profiles of ambient and snowpack air exhibited large concentration gradients through the top ∼10 cm of the snowpack, implying a flux of carbonyl compounds from the surface to the atmosphere. From vertical profile and eddy diffusivity measurements made simultaneously on 22 April, acetaldehyde and acetone fluxes of 4.2(±2.1)×10 8 and 6.2(±4.2)×10 8 molecules cm −2 s −1 were derived, respectively. For this day, the sources and sinks of CH 3CHO from gas phase chemistry were estimated. The result showed that the snowpack flux of CH 3CHO to the atmosphere was as large as the calculated CH 3CHO loss rate from known atmospheric gas phase reactions, and at least 40 times larger (in the surface layer) than the volumetric rate of acetaldehyde produced from the assumed main atmospheric gas phase reaction, i.e. reaction of ethane with hydroxyl radicals. In addition, acetaldehyde bulk snow phase measurements showed that acetaldehyde was produced in or on the snow phase, likely from a photochemical origin. The time series for the observed CH 3C(O)CH 3, ozone (O 3), and propane during PSE 1995, PSE 1998, and ALERT 2000 showed a consistent anti-correlation between acetone and O 3 and between acetone and propane. However, our data and model simulations showed that the acetone increase during ozone depletion events cannot be explained by gas phase chemistry involving propane oxidation. These results suggest that the snowpack is a significant source of acetaldehyde and acetone to the Arctic boundary layer.</description><subject>Acetaldehyde</subject><subject>Acetone</subject><subject>Arctic chemistry</subject><subject>Polar Sunrise Experiment 2000</subject><subject>Snowpack</subject><issn>1352-2310</issn><issn>1873-2844</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2002</creationdate><recordtype>article</recordtype><recordid>eNqFUE1LAzEUDKJgrf4EISfRw2o-drvJSUrxCwoequAtZJMXG91u1mSr9N8bWz17eW94zAzzBqFTSi4poZOrBeUVKxin5JywC0IoqQu-h0ZU1Lxgoiz3M_6jHKKjlN4IIbyW9Qi9LLrw1WvzjvsYDKTku1ccHNYGBt1aWG4sYN3Z7SF0gH2HhyXgaTSDN1gPq5D6JcSMm7DurI4b3OoNxGN04HSb4OR3j9Hz7c3T7L6YP949zKbzwnAuhjxLp4WTUAlW01JIoGAawhvTVM6xpjYAdiKFdZRWE-akFEIDEOYYNZw4PkZnO9-c_2MNaVArnwy0re4grJOiohJUMpmJ1Y5oYkgpglN99KucV1GifnpU2x7VT0mKMLXtUfGsu97pIH_x6SGqZDx0BqyPYAZlg__H4Ru6s3uo</recordid><startdate>20020501</startdate><enddate>20020501</enddate><creator>Guimbaud, Christophe</creator><creator>Grannas, Amanda M</creator><creator>Shepson, Paul B</creator><creator>Fuentes, José D</creator><creator>Boudries, Hacene</creator><creator>Bottenheim, Jan W</creator><creator>Dominé, Florent</creator><creator>Houdier, Stephan</creator><creator>Perrier, Sébastien</creator><creator>Biesenthal, Thomas B</creator><creator>Splawn, Bryan G</creator><general>Elsevier Ltd</general><scope>AAYXX</scope><scope>CITATION</scope><scope>7TG</scope><scope>KL.</scope></search><sort><creationdate>20020501</creationdate><title>Snowpack processing of acetaldehyde and acetone in the Arctic atmospheric boundary layer</title><author>Guimbaud, Christophe ; Grannas, Amanda M ; Shepson, Paul B ; Fuentes, José D ; Boudries, Hacene ; Bottenheim, Jan W ; Dominé, Florent ; Houdier, Stephan ; Perrier, Sébastien ; Biesenthal, Thomas B ; Splawn, Bryan G</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c338t-c34fa8f9e58271489e1ecb03bcb5ff2b7ceed698df11562f9988aee02f21c30f3</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2002</creationdate><topic>Acetaldehyde</topic><topic>Acetone</topic><topic>Arctic chemistry</topic><topic>Polar Sunrise Experiment 2000</topic><topic>Snowpack</topic><toplevel>peer_reviewed</toplevel><toplevel>online_resources</toplevel><creatorcontrib>Guimbaud, Christophe</creatorcontrib><creatorcontrib>Grannas, Amanda M</creatorcontrib><creatorcontrib>Shepson, Paul B</creatorcontrib><creatorcontrib>Fuentes, José D</creatorcontrib><creatorcontrib>Boudries, Hacene</creatorcontrib><creatorcontrib>Bottenheim, Jan W</creatorcontrib><creatorcontrib>Dominé, Florent</creatorcontrib><creatorcontrib>Houdier, Stephan</creatorcontrib><creatorcontrib>Perrier, Sébastien</creatorcontrib><creatorcontrib>Biesenthal, Thomas B</creatorcontrib><creatorcontrib>Splawn, Bryan G</creatorcontrib><collection>CrossRef</collection><collection>Meteorological & Geoastrophysical Abstracts</collection><collection>Meteorological & Geoastrophysical Abstracts - Academic</collection><jtitle>Atmospheric environment (1994)</jtitle></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext</fulltext></delivery><addata><au>Guimbaud, Christophe</au><au>Grannas, Amanda M</au><au>Shepson, Paul B</au><au>Fuentes, José D</au><au>Boudries, Hacene</au><au>Bottenheim, Jan W</au><au>Dominé, Florent</au><au>Houdier, Stephan</au><au>Perrier, Sébastien</au><au>Biesenthal, Thomas B</au><au>Splawn, Bryan G</au><format>journal</format><genre>article</genre><ristype>JOUR</ristype><atitle>Snowpack processing of acetaldehyde and acetone in the Arctic atmospheric boundary layer</atitle><jtitle>Atmospheric environment (1994)</jtitle><date>2002-05-01</date><risdate>2002</risdate><volume>36</volume><issue>15</issue><spage>2743</spage><epage>2752</epage><pages>2743-2752</pages><issn>1352-2310</issn><eissn>1873-2844</eissn><abstract>Acetaldehyde (CH 3CHO) and acetone (CH 3C(O)CH 3) concentrations in ambient air, in snowpack air, and bulk snow were determined at Alert, Nunavut, Canada, as a part of the Polar Sunrise Experiment (PSE): ALERT 2000. During the period of continuous sunlight, vertical profiles of ambient and snowpack air exhibited large concentration gradients through the top ∼10 cm of the snowpack, implying a flux of carbonyl compounds from the surface to the atmosphere. From vertical profile and eddy diffusivity measurements made simultaneously on 22 April, acetaldehyde and acetone fluxes of 4.2(±2.1)×10 8 and 6.2(±4.2)×10 8 molecules cm −2 s −1 were derived, respectively. For this day, the sources and sinks of CH 3CHO from gas phase chemistry were estimated. The result showed that the snowpack flux of CH 3CHO to the atmosphere was as large as the calculated CH 3CHO loss rate from known atmospheric gas phase reactions, and at least 40 times larger (in the surface layer) than the volumetric rate of acetaldehyde produced from the assumed main atmospheric gas phase reaction, i.e. reaction of ethane with hydroxyl radicals. In addition, acetaldehyde bulk snow phase measurements showed that acetaldehyde was produced in or on the snow phase, likely from a photochemical origin. The time series for the observed CH 3C(O)CH 3, ozone (O 3), and propane during PSE 1995, PSE 1998, and ALERT 2000 showed a consistent anti-correlation between acetone and O 3 and between acetone and propane. However, our data and model simulations showed that the acetone increase during ozone depletion events cannot be explained by gas phase chemistry involving propane oxidation. These results suggest that the snowpack is a significant source of acetaldehyde and acetone to the Arctic boundary layer.</abstract><pub>Elsevier Ltd</pub><doi>10.1016/S1352-2310(02)00107-3</doi><tpages>10</tpages></addata></record>
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subjects	Acetaldehyde Acetone Arctic chemistry Polar Sunrise Experiment 2000 Snowpack
title	Snowpack processing of acetaldehyde and acetone in the Arctic atmospheric boundary layer
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