Are methyl halides produced on all ice surfaces? Observations from snow-laden field sites

We present data collected from a number of snow-covered environments including two polar locations (Summit, Greenland and the South Pole) and two mid-latitude regions (a remote site in northern Michigan, and Niwot Ridge, Colorado). At each site, concentrations of CH3I and C2H5I were enhanced within...

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Bibliographic Details
Published in:Atmospheric Environment
Main Authors: Swanson, Aaron L, Blake, Nicola J, Blake, D R, Rowland, F Sherwood, Dibb, Jack E., Lefer, Barry, Atlas, E L
Format: Text
Language:unknown
Published: University of New Hampshire Scholars' Repository 2007
Subjects:
Snow chemistry
Methyl iodide
Methyl bromide
Organohalides
Snow composition
Atmospheric Sciences
Greenland
South Pole
South pole
Online Access:https://scholars.unh.edu/earthsci_facpub/53
https://doi.org/10.1016/j.atmosenv.2006.11.064
Description
Summary:We present data collected from a number of snow-covered environments including two polar locations (Summit, Greenland and the South Pole) and two mid-latitude regions (a remote site in northern Michigan, and Niwot Ridge, Colorado). At each site, concentrations of CH3I and C2H5I were enhanced within the interstitial air near the snow surface, compared to levels in boundary layer air. Fluxes of CH3Br from surface snow to the atmosphere were observed at each site except Niwot Ridge, where CH3Brappeared to have a sink. The mid-latitude sites showed significant emissions of CH3Cl, mostly originating at the ground surface and traveling up through the snow, while at the polar locations CH3Cl emissions from firn air were relatively small. In general, methyl halide mixing ratios in firn air were significantly greater at Summit than at the South Pole, with Summit showing a strong diurnal cycle in the production of alkyl halides that was well correlated with actinic radiation and firn temperature. We suggest that the most likely route to alkyl halide formation is through an acid catalyzed nucleophilic substitution of an alcohol type function by a halide, both of which should be preferentially segregated to the quasi-liquid layer at the surface of the snow grains. A series of experiments using a snow-filled quartz chamber irradiated by natural sunlight allowed estimation of emission trends that were hard to measure in the natural snowpack. These static chamber experiments confirmed significant production of the primary alkyl halides, following the orderCH3Cl>CH3Br>C2H5Cl>CH3I>C2H5Br>C2H5I>1-C3H7Br>1-C3H7I. Our observations at all four locations, including polar and mid-latitude sites, imply that alkyl halide production may be associated with all surface snows.

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