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The role of the snowpack on the fate of a-HCH in an atmospheric chemistry-transport model.

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The role of the snowpack on the fate of a-HCH in an atmospheric chemistry-transport model. / Hansen, Kaj M.; Halsall, Crispin J.; Christensen, Jesper et al.
In: Environmental Science and Technology, Vol. 42, No. 8, 15.04.2008, p. 2943-2948.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Hansen, KM, Halsall, CJ, Christensen, J, Brandt, J, Frohn, LM, Geels, C & Skjøth, CA 2008, 'The role of the snowpack on the fate of a-HCH in an atmospheric chemistry-transport model.', Environmental Science and Technology, vol. 42, no. 8, pp. 2943-2948. https://doi.org/10.1021/es7030328

APA

Hansen, K. M., Halsall, C. J., Christensen, J., Brandt, J., Frohn, L. M., Geels, C., & Skjøth, C. A. (2008). The role of the snowpack on the fate of a-HCH in an atmospheric chemistry-transport model. Environmental Science and Technology, 42(8), 2943-2948. https://doi.org/10.1021/es7030328

Vancouver

Hansen KM, Halsall CJ, Christensen J, Brandt J, Frohn LM, Geels C et al. The role of the snowpack on the fate of a-HCH in an atmospheric chemistry-transport model. Environmental Science and Technology. 2008 Apr 15;42(8):2943-2948. doi: 10.1021/es7030328

Author

Hansen, Kaj M. ; Halsall, Crispin J. ; Christensen, Jesper et al. / The role of the snowpack on the fate of a-HCH in an atmospheric chemistry-transport model. In: Environmental Science and Technology. 2008 ; Vol. 42, No. 8. pp. 2943-2948.

Bibtex

@article{058e60ebd87a4cf592d66753c201a089,
title = "The role of the snowpack on the fate of a-HCH in an atmospheric chemistry-transport model.",
abstract = "A dynamic snowpack module was implemented in the Danish Eulerian Hemispheric Model Persistant Organic Pollutants (DEHM-POP), an atmospheric chemistry-transport model designed to study the environmental fate of persistent organic pollutants in the Northern Hemisphere. The role of the snowpack on the fate of α-hexachlorocyclohexane (α-HCH) was investigated by making simulations both with and without the formation of a snowpack and comparing model results with data from 21 air monitoring sites. The inclusion of a dynamic snowpack module in the DEHM-POP model generally improves the fit between modeled and observed α-HCH air concentrations for the winter and spring seasons and the overall correlation coefficient between predicted and observed concentrations are improved at 8 of the sites. The predicted snowpack concentrations are in good agreement with the few available snow measurements from the Arctic. The presence of a snowpack increases surface boundary layer air concentrations of α-HCH at midlatitudes, while the effect is more pronounced in the Arctic due to the longer periods of snow cover. The results indicate that the snowpack module in DEHM-POP acts as a fast-exchanging temporary storage medium for α-HCH, as significant fractions were rapidly revolatilized back into the atmosphere following deposition with snowfall, although the current parametrization for vapor-exchange probably over emphasizes this process. Nonetheless, increased air concentrations observed between March and May (“spring maximum events”; SME) at several high latitude monitoring stations are also predicted by the model. The model results indicate that the SMEs are associated with the revolatilization of previously deposited chemical from the snowpack, following a reduction in the capacity of the snowpack to retain α-HCH with increasing temperatures toward the end of the winter period, rather than the actual melting of the snowpack. The SMEs are not predicted at all the Arctic monitoring sites by the model, and the significance of the snowpack in controlling these in the model is, therefore, open to question given the uncertainties in the snow−air partition coefficient (Ksa) and the reliance of the model on a one-layer snowpack rather than a multilayered snowpack.",
author = "Hansen, {Kaj M.} and Halsall, {Crispin J.} and Jesper Christensen and J{\o}rgen Brandt and Frohn, {Lise M.} and Camilla Geels and Skj{\o}th, {Carsten Ambelas}",
year = "2008",
month = apr,
day = "15",
doi = "10.1021/es7030328",
language = "English",
volume = "42",
pages = "2943--2948",
journal = "Environmental Science and Technology",
issn = "0013-936X",
publisher = "American Chemical Society",
number = "8",

}

RIS

TY - JOUR

T1 - The role of the snowpack on the fate of a-HCH in an atmospheric chemistry-transport model.

AU - Hansen, Kaj M.

AU - Halsall, Crispin J.

AU - Christensen, Jesper

AU - Brandt, Jørgen

AU - Frohn, Lise M.

AU - Geels, Camilla

AU - Skjøth, Carsten Ambelas

PY - 2008/4/15

Y1 - 2008/4/15

N2 - A dynamic snowpack module was implemented in the Danish Eulerian Hemispheric Model Persistant Organic Pollutants (DEHM-POP), an atmospheric chemistry-transport model designed to study the environmental fate of persistent organic pollutants in the Northern Hemisphere. The role of the snowpack on the fate of α-hexachlorocyclohexane (α-HCH) was investigated by making simulations both with and without the formation of a snowpack and comparing model results with data from 21 air monitoring sites. The inclusion of a dynamic snowpack module in the DEHM-POP model generally improves the fit between modeled and observed α-HCH air concentrations for the winter and spring seasons and the overall correlation coefficient between predicted and observed concentrations are improved at 8 of the sites. The predicted snowpack concentrations are in good agreement with the few available snow measurements from the Arctic. The presence of a snowpack increases surface boundary layer air concentrations of α-HCH at midlatitudes, while the effect is more pronounced in the Arctic due to the longer periods of snow cover. The results indicate that the snowpack module in DEHM-POP acts as a fast-exchanging temporary storage medium for α-HCH, as significant fractions were rapidly revolatilized back into the atmosphere following deposition with snowfall, although the current parametrization for vapor-exchange probably over emphasizes this process. Nonetheless, increased air concentrations observed between March and May (“spring maximum events”; SME) at several high latitude monitoring stations are also predicted by the model. The model results indicate that the SMEs are associated with the revolatilization of previously deposited chemical from the snowpack, following a reduction in the capacity of the snowpack to retain α-HCH with increasing temperatures toward the end of the winter period, rather than the actual melting of the snowpack. The SMEs are not predicted at all the Arctic monitoring sites by the model, and the significance of the snowpack in controlling these in the model is, therefore, open to question given the uncertainties in the snow−air partition coefficient (Ksa) and the reliance of the model on a one-layer snowpack rather than a multilayered snowpack.

AB - A dynamic snowpack module was implemented in the Danish Eulerian Hemispheric Model Persistant Organic Pollutants (DEHM-POP), an atmospheric chemistry-transport model designed to study the environmental fate of persistent organic pollutants in the Northern Hemisphere. The role of the snowpack on the fate of α-hexachlorocyclohexane (α-HCH) was investigated by making simulations both with and without the formation of a snowpack and comparing model results with data from 21 air monitoring sites. The inclusion of a dynamic snowpack module in the DEHM-POP model generally improves the fit between modeled and observed α-HCH air concentrations for the winter and spring seasons and the overall correlation coefficient between predicted and observed concentrations are improved at 8 of the sites. The predicted snowpack concentrations are in good agreement with the few available snow measurements from the Arctic. The presence of a snowpack increases surface boundary layer air concentrations of α-HCH at midlatitudes, while the effect is more pronounced in the Arctic due to the longer periods of snow cover. The results indicate that the snowpack module in DEHM-POP acts as a fast-exchanging temporary storage medium for α-HCH, as significant fractions were rapidly revolatilized back into the atmosphere following deposition with snowfall, although the current parametrization for vapor-exchange probably over emphasizes this process. Nonetheless, increased air concentrations observed between March and May (“spring maximum events”; SME) at several high latitude monitoring stations are also predicted by the model. The model results indicate that the SMEs are associated with the revolatilization of previously deposited chemical from the snowpack, following a reduction in the capacity of the snowpack to retain α-HCH with increasing temperatures toward the end of the winter period, rather than the actual melting of the snowpack. The SMEs are not predicted at all the Arctic monitoring sites by the model, and the significance of the snowpack in controlling these in the model is, therefore, open to question given the uncertainties in the snow−air partition coefficient (Ksa) and the reliance of the model on a one-layer snowpack rather than a multilayered snowpack.

UR - http://www.scopus.com/inward/record.url?scp=42149165467&partnerID=8YFLogxK

U2 - 10.1021/es7030328

DO - 10.1021/es7030328

M3 - Journal article

VL - 42

SP - 2943

EP - 2948

JO - Environmental Science and Technology

JF - Environmental Science and Technology

SN - 0013-936X

IS - 8

ER -