The impact of snow accumulation on the active layer thermal regime in high Arctic soils

This study quantifies the impacts of snow augmentation and the timing of snow accumulation on the soil thermal regime at the Cape Bounty Arctic Watershed Observatory (CBAWO), in the Canadian High Arctic. Monthly soil temperatures between December and March 2006-2007 were 7.7 to 9.9°C warmer beneath...

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Bibliographic Details
Published inVadose zone journal Vol. 12; no. 1; pp. 1 - 13
Main Authors Lafrenière, Melissa J, Laurin, Emil, Lamoureux, Scott F
Format Journal Article
LanguageEnglish
Published Soil Science Society of America 01.02.2013
The Soil Science Society of America, Inc
Subjects
active layer
air
Arctic Archipelago
arctic environment
Arctic region
Canada
Cape Bounty Arctic Watershed Observatory
depth
drainage basins
field studies
ground-surface temperature
Melville Island
Nunavut
Parry Islands
permafrost
Queen Elizabeth Islands
seasonal variations
snow
snow cover
soils
temperature
thermal properties
tundra
unsaturated zone
vegetation
West River basin
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Summary:This study quantifies the impacts of snow augmentation and the timing of snow accumulation on the soil thermal regime at the Cape Bounty Arctic Watershed Observatory (CBAWO), in the Canadian High Arctic. Monthly soil temperatures between December and March 2006-2007 were 7.7 to 9.9°C warmer beneath a deep drift (54 cm) relative to soils beneath ambient (unamended or background) snow conditions (10 cm). Although air temperatures and total snow accumulation at the sites in 2007-2008 were very similar to the previous winter, the mean monthly soil temperatures beneath two snow drifts (50 and 88 cm) were only 0.2 to 5.7°C warmer for January through March than soils subject to ambient snow depths (18 and 35 cm). Results demonstrate that the timing of snow accumulation was more important than snow depth in determining winter soil temperatures. In 2006-2007, snow cover insulated soils by early November, while in 2007-2008 there was insufficient snow cover to insulate soils until late January 2008. In 2006-2007, winter (December-March) soil temperatures beneath the deepest snow (54 cm) exceeded winter air temperatures by 6°C, and mean annual air temperatures by 1°C, while in 2007-2008 winter soil temperatures beneath 88 cm of snow were only 0.3°C warmer than air, and mean annual temperatures were 2.4°C cooler than air. There was a weak but significant inverse correlation between the maximum active layer thickness and the snow depth; however, this correlation was more pronounced for snow depths below approximately 30 cm. This study demonstrates that an understanding of the timing of projected increases in winter precipitation is necessary to predict changes in the active layer's thermal, hydrological, and biogeochemical response to regional climate change.
Bibliography:Snow augmentation experiments conducted over two consecutive seasons found that inter‐annual variability in the timing of snow accumulation had a greater impact on soil temperatures than changes in snow depth. Thus, predicting the response of permafrost to climate change will be sensitive to both the magnitude and timing of autumn snowfall.
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ISSN:1539-1663
1539-1663
DOI:10.2136/vzj2012.0058