Modeling chemistry in and above snow at Summit, Greenland – Part 2: Impact of snowpack chemistry on the oxidation capacity of the boundary layer

The chemical composition of the boundary layer in snow covered regions is impacted by chemistry in the snowpack via uptake, processing, and emission of atmospheric trace gases. We use the coupled one-dimensional (1-D) snow chemistry and atmospheric boundary layer model MISTRA-SNOW to study the impac...

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Published in:Atmospheric Chemistry and Physics
Main Authors: Thomas, J. L., Dibb, J. E., Huey, L. G., Liao, J., Tanner, D., Lefer, B., von Glasow, R., Stutz, J.
Format: Article in Journal/Newspaper
Language:unknown
Published: 2012
Subjects:
Greenland
Online Access:https://ueaeprints.uea.ac.uk/id/eprint/39875/
https://doi.org/10.5194/acp-12-6537-2012
id ftuniveastangl:oai:ueaeprints.uea.ac.uk:39875
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spelling ftuniveastangl:oai:ueaeprints.uea.ac.uk:39875 2024-04-21T08:03:44+00:00 Modeling chemistry in and above snow at Summit, Greenland – Part 2: Impact of snowpack chemistry on the oxidation capacity of the boundary layer Thomas, J. L. Dibb, J. E. Huey, L. G. Liao, J. Tanner, D. Lefer, B. von Glasow, R. Stutz, J. 2012 https://ueaeprints.uea.ac.uk/id/eprint/39875/ https://doi.org/10.5194/acp-12-6537-2012 unknown Thomas, J. L., Dibb, J. E., Huey, L. G., Liao, J., Tanner, D., Lefer, B., von Glasow, R. and Stutz, J. (2012) Modeling chemistry in and above snow at Summit, Greenland – Part 2: Impact of snowpack chemistry on the oxidation capacity of the boundary layer. Atmospheric Chemistry and Physics, 12 (14). pp. 6537-6554. ISSN 1680-7324 doi:10.5194/acp-12-6537-2012 Article PeerReviewed 2012 ftuniveastangl https://doi.org/10.5194/acp-12-6537-2012 2024-03-27T17:54:51Z The chemical composition of the boundary layer in snow covered regions is impacted by chemistry in the snowpack via uptake, processing, and emission of atmospheric trace gases. We use the coupled one-dimensional (1-D) snow chemistry and atmospheric boundary layer model MISTRA-SNOW to study the impact of snowpack chemistry on the oxidation capacity of the boundary layer. The model includes gas phase photochemistry and chemical reactions both in the interstitial air and the atmosphere. While it is acknowledged that the chemistry occurring at ice surfaces may consist of a true quasi-liquid layer and/or a concentrated brine layer, lack of additional knowledge requires that this chemistry be modeled as primarily aqueous chemistry occurring in a liquid-like layer (LLL) on snow grains. The model has been recently compared with BrO and NO data taken on 10 June–13 June 2008 as part of the Greenland Summit Halogen-HOx experiment (GSHOX). In the present study, we use the same focus period to investigate the influence of snowpack derived chemistry on OH and HOx + RO2 in the boundary layer. We compare model results with chemical ionization mass spectrometry (CIMS) measurements of the hydroxyl radical (OH) and of the hydroperoxyl radical (HO2) plus the sum of all organic peroxy radicals (RO2) taken at Summit during summer 2008. Using sensitivity runs we show that snowpack influenced nitrogen cycling and bromine chemistry both increase the oxidation capacity of the boundary layer and that together they increase the mid-day OH concentrations. Bromine chemistry increases the OH concentration by 10–18% (10% at noon LT), while snow sourced NOx increases OH concentrations by 20–50% (27% at noon LT). We show for the first time, using a coupled one-dimensional snowpack-boundary layer model, that air-snow interactions impact the oxidation capacity of the boundary layer and that it is not possible to match measured OH levels without snowpack NOx and halogen emissions. Model predicted HONO compared with mistchamber measurements suggests ... Article in Journal/Newspaper Greenland University of East Anglia: UEA Digital Repository Atmospheric Chemistry and Physics 12 14 6537 6554
institution Open Polar
collection University of East Anglia: UEA Digital Repository
op_collection_id ftuniveastangl
language unknown
description The chemical composition of the boundary layer in snow covered regions is impacted by chemistry in the snowpack via uptake, processing, and emission of atmospheric trace gases. We use the coupled one-dimensional (1-D) snow chemistry and atmospheric boundary layer model MISTRA-SNOW to study the impact of snowpack chemistry on the oxidation capacity of the boundary layer. The model includes gas phase photochemistry and chemical reactions both in the interstitial air and the atmosphere. While it is acknowledged that the chemistry occurring at ice surfaces may consist of a true quasi-liquid layer and/or a concentrated brine layer, lack of additional knowledge requires that this chemistry be modeled as primarily aqueous chemistry occurring in a liquid-like layer (LLL) on snow grains. The model has been recently compared with BrO and NO data taken on 10 June–13 June 2008 as part of the Greenland Summit Halogen-HOx experiment (GSHOX). In the present study, we use the same focus period to investigate the influence of snowpack derived chemistry on OH and HOx + RO2 in the boundary layer. We compare model results with chemical ionization mass spectrometry (CIMS) measurements of the hydroxyl radical (OH) and of the hydroperoxyl radical (HO2) plus the sum of all organic peroxy radicals (RO2) taken at Summit during summer 2008. Using sensitivity runs we show that snowpack influenced nitrogen cycling and bromine chemistry both increase the oxidation capacity of the boundary layer and that together they increase the mid-day OH concentrations. Bromine chemistry increases the OH concentration by 10–18% (10% at noon LT), while snow sourced NOx increases OH concentrations by 20–50% (27% at noon LT). We show for the first time, using a coupled one-dimensional snowpack-boundary layer model, that air-snow interactions impact the oxidation capacity of the boundary layer and that it is not possible to match measured OH levels without snowpack NOx and halogen emissions. Model predicted HONO compared with mistchamber measurements suggests ...
format Article in Journal/Newspaper
author Thomas, J. L.
Dibb, J. E.
Huey, L. G.
Liao, J.
Tanner, D.
Lefer, B.
von Glasow, R.
Stutz, J.
spellingShingle Thomas, J. L.
Dibb, J. E.
Huey, L. G.
Liao, J.
Tanner, D.
Lefer, B.
von Glasow, R.
Stutz, J.
Modeling chemistry in and above snow at Summit, Greenland – Part 2: Impact of snowpack chemistry on the oxidation capacity of the boundary layer
author_facet Thomas, J. L.
Dibb, J. E.
Huey, L. G.
Liao, J.
Tanner, D.
Lefer, B.
von Glasow, R.
Stutz, J.
author_sort Thomas, J. L.
title Modeling chemistry in and above snow at Summit, Greenland – Part 2: Impact of snowpack chemistry on the oxidation capacity of the boundary layer
title_short Modeling chemistry in and above snow at Summit, Greenland – Part 2: Impact of snowpack chemistry on the oxidation capacity of the boundary layer
title_full Modeling chemistry in and above snow at Summit, Greenland – Part 2: Impact of snowpack chemistry on the oxidation capacity of the boundary layer
title_fullStr Modeling chemistry in and above snow at Summit, Greenland – Part 2: Impact of snowpack chemistry on the oxidation capacity of the boundary layer
title_full_unstemmed Modeling chemistry in and above snow at Summit, Greenland – Part 2: Impact of snowpack chemistry on the oxidation capacity of the boundary layer
title_sort modeling chemistry in and above snow at summit, greenland – part 2: impact of snowpack chemistry on the oxidation capacity of the boundary layer
publishDate 2012
url https://ueaeprints.uea.ac.uk/id/eprint/39875/
https://doi.org/10.5194/acp-12-6537-2012
genre Greenland
genre_facet Greenland
op_relation Thomas, J. L., Dibb, J. E., Huey, L. G., Liao, J., Tanner, D., Lefer, B., von Glasow, R. and Stutz, J. (2012) Modeling chemistry in and above snow at Summit, Greenland – Part 2: Impact of snowpack chemistry on the oxidation capacity of the boundary layer. Atmospheric Chemistry and Physics, 12 (14). pp. 6537-6554. ISSN 1680-7324
doi:10.5194/acp-12-6537-2012
op_doi https://doi.org/10.5194/acp-12-6537-2012
container_title Atmospheric Chemistry and Physics
container_volume 12
container_issue 14
container_start_page 6537
op_container_end_page 6554
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