Observations of atmospheric chemical deposition to high Arctic snow

Observations of atmospheric chemical deposition to high Arctic snow

Rapidly rising temperatures and loss of snow and ice cover have demonstrated the unique vulnerability of the high Arctic to climate change. There are major uncertainties in modelling the chemical depositional and scavenging processes of Arctic snow. To that end, fresh snow samples collected on avera...

Full description

Bibliographic Details
Main Authors: K. M. Macdonald, S. Sharma, D. Toom, A. Chivulescu, S. Hanna, A. K. Bertram, A. Platt, M. Elsasser, L. Huang, D. Tarasick, N. Chellman, J. R. McConnell, H. Bozem, D. Kunkel, Y. D. Lei, G. J. Evans, J. P. D. Abbatt
Format: Article
Language:English
Published: Copernicus Publications 2017-05-01
Series:Atmospheric Chemistry and Physics
Online Access:http://www.atmos-chem-phys.net/17/5775/2017/acp-17-5775-2017.pdf
id doaj-41498726233547fea93e21fb605a1e61
record_format Article
spelling doaj-41498726233547fea93e21fb605a1e612020-11-24T22:05:30ZengCopernicus PublicationsAtmospheric Chemistry and Physics1680-73161680-73242017-05-011795775578810.5194/acp-17-5775-2017Observations of atmospheric chemical deposition to high Arctic snowK. M. Macdonald0S. Sharma1D. Toom2A. Chivulescu3S. Hanna4A. K. Bertram5A. Platt6M. Elsasser7L. Huang8D. Tarasick9N. Chellman10J. R. McConnell11H. Bozem12D. Kunkel13Y. D. Lei14G. J. Evans15J. P. D. Abbatt16Department of Chemical Engineering and Applied Chemistry, University of Toronto, Toronto, M5S 3E5, CanadaClimate Research Divisions, Environment and Climate Change Canada, Toronto, M3H 5T4, CanadaClimate Research Divisions, Environment and Climate Change Canada, Toronto, M3H 5T4, CanadaClimate Research Divisions, Environment and Climate Change Canada, Toronto, M3H 5T4, CanadaDepartment of Chemistry, University of British Columbia, Vancouver, V6T 1Z1, CanadaDepartment of Chemistry, University of British Columbia, Vancouver, V6T 1Z1, CanadaClimate Research Divisions, Environment and Climate Change Canada, Toronto, M3H 5T4, CanadaClimate Research Divisions, Environment and Climate Change Canada, Toronto, M3H 5T4, CanadaClimate Research Divisions, Environment and Climate Change Canada, Toronto, M3H 5T4, CanadaAir Quality Research Divisions, Environment and Climate Change Canada, Toronto, M3H 5T4, CanadaDesert Research Institute, Reno, 89512, USADesert Research Institute, Reno, 89512, USAInstitute for Atmospheric Physics, Johannes Gutenberg University Mainz, Mainz, 55128, GermanyInstitute for Atmospheric Physics, Johannes Gutenberg University Mainz, Mainz, 55128, GermanyDepartment of Chemical Engineering and Applied Chemistry, University of Toronto, Toronto, M5S 3E5, CanadaDepartment of Chemical Engineering and Applied Chemistry, University of Toronto, Toronto, M5S 3E5, CanadaDepartment of Chemistry, University of Toronto, Toronto, M5S 3H6, CanadaRapidly rising temperatures and loss of snow and ice cover have demonstrated the unique vulnerability of the high Arctic to climate change. There are major uncertainties in modelling the chemical depositional and scavenging processes of Arctic snow. To that end, fresh snow samples collected on average every 4 days at Alert, Nunavut, from September 2014 to June 2015 were analyzed for black carbon, major ions, and metals, and their concentrations and fluxes were reported. Comparison with simultaneous measurements of atmospheric aerosol mass loadings yields effective deposition velocities that encompass all processes by which the atmospheric species are transferred to the snow. It is inferred from these values that dry deposition is the dominant removal mechanism for several compounds over the winter while wet deposition increased in importance in the fall and spring, possibly due to enhanced scavenging by mixed-phase clouds. Black carbon aerosol was the least efficiently deposited species to the snow.http://www.atmos-chem-phys.net/17/5775/2017/acp-17-5775-2017.pdf
collection DOAJ
language English
format Article
sources DOAJ
author K. M. Macdonald
S. Sharma
D. Toom
A. Chivulescu
S. Hanna
A. K. Bertram
A. Platt
M. Elsasser
L. Huang
D. Tarasick
N. Chellman
J. R. McConnell
H. Bozem
D. Kunkel
Y. D. Lei
G. J. Evans
J. P. D. Abbatt
spellingShingle K. M. Macdonald
S. Sharma
D. Toom
A. Chivulescu
S. Hanna
A. K. Bertram
A. Platt
M. Elsasser
L. Huang
D. Tarasick
N. Chellman
J. R. McConnell
H. Bozem
D. Kunkel
Y. D. Lei
G. J. Evans
J. P. D. Abbatt
Observations of atmospheric chemical deposition to high Arctic snow
Atmospheric Chemistry and Physics
author_facet K. M. Macdonald
S. Sharma
D. Toom
A. Chivulescu
S. Hanna
A. K. Bertram
A. Platt
M. Elsasser
L. Huang
D. Tarasick
N. Chellman
J. R. McConnell
H. Bozem
D. Kunkel
Y. D. Lei
G. J. Evans
J. P. D. Abbatt
author_sort K. M. Macdonald
title Observations of atmospheric chemical deposition to high Arctic snow
title_short Observations of atmospheric chemical deposition to high Arctic snow
title_full Observations of atmospheric chemical deposition to high Arctic snow
title_fullStr Observations of atmospheric chemical deposition to high Arctic snow
title_full_unstemmed Observations of atmospheric chemical deposition to high Arctic snow
title_sort observations of atmospheric chemical deposition to high arctic snow
publisher Copernicus Publications
series Atmospheric Chemistry and Physics
issn 1680-7316
1680-7324
publishDate 2017-05-01
description Rapidly rising temperatures and loss of snow and ice cover have demonstrated the unique vulnerability of the high Arctic to climate change. There are major uncertainties in modelling the chemical depositional and scavenging processes of Arctic snow. To that end, fresh snow samples collected on average every 4 days at Alert, Nunavut, from September 2014 to June 2015 were analyzed for black carbon, major ions, and metals, and their concentrations and fluxes were reported. Comparison with simultaneous measurements of atmospheric aerosol mass loadings yields effective deposition velocities that encompass all processes by which the atmospheric species are transferred to the snow. It is inferred from these values that dry deposition is the dominant removal mechanism for several compounds over the winter while wet deposition increased in importance in the fall and spring, possibly due to enhanced scavenging by mixed-phase clouds. Black carbon aerosol was the least efficiently deposited species to the snow.
url http://www.atmos-chem-phys.net/17/5775/2017/acp-17-5775-2017.pdf
work_keys_str_mv AT kmmacdonald observationsofatmosphericchemicaldepositiontohigharcticsnow
AT ssharma observationsofatmosphericchemicaldepositiontohigharcticsnow
AT dtoom observationsofatmosphericchemicaldepositiontohigharcticsnow
AT achivulescu observationsofatmosphericchemicaldepositiontohigharcticsnow
AT shanna observationsofatmosphericchemicaldepositiontohigharcticsnow
AT akbertram observationsofatmosphericchemicaldepositiontohigharcticsnow
AT aplatt observationsofatmosphericchemicaldepositiontohigharcticsnow
AT melsasser observationsofatmosphericchemicaldepositiontohigharcticsnow
AT lhuang observationsofatmosphericchemicaldepositiontohigharcticsnow
AT dtarasick observationsofatmosphericchemicaldepositiontohigharcticsnow
AT nchellman observationsofatmosphericchemicaldepositiontohigharcticsnow
AT jrmcconnell observationsofatmosphericchemicaldepositiontohigharcticsnow
AT hbozem observationsofatmosphericchemicaldepositiontohigharcticsnow
AT dkunkel observationsofatmosphericchemicaldepositiontohigharcticsnow
AT ydlei observationsofatmosphericchemicaldepositiontohigharcticsnow
AT gjevans observationsofatmosphericchemicaldepositiontohigharcticsnow
AT jpdabbatt observationsofatmosphericchemicaldepositiontohigharcticsnow
_version_ 1725826098476875776

Similar Items