Snowmelt -frozen soil characteristics for a subarctic setting
The pathways of soil water in cold climates are influenced, in addition to the normal forces, by the presence of permafrost and the temperature gradients in the soil system, whereas the infiltration of surface water into the soil system is a function of moisture levels, soil type and condition of th...
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University of Alaska, Institute of Water Resources
1978
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| Online Access: | http://hdl.handle.net/11122/1865 |
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ftunivalaska:oai:scholarworks.alaska.edu:11122/1865 |
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ftunivalaska:oai:scholarworks.alaska.edu:11122/1865 2023-05-15T17:57:34+02:00 Snowmelt -frozen soil characteristics for a subarctic setting Kane, Douglas L. Seifert, Richard D. Fox, John D. Taylor, George S. 1978-01 http://hdl.handle.net/11122/1865 unknown University of Alaska, Institute of Water Resources IWR;no. 84 http://hdl.handle.net/11122/1865 Technical Report 1978 ftunivalaska 2023-02-23T21:35:46Z The pathways of soil water in cold climates are influenced, in addition to the normal forces, by the presence of permafrost and the temperature gradients in the soil system, whereas the infiltration of surface water into the soil system is a function of moisture levels, soil type and condition of the soil (whether it is frozen or not). Snowfall, with subsequent surface storage over a period of several months, typifies Alaskan winters. This snowfall often accounts for 50 per cent or more of the annual precipitation, with ablation occurring over a time span of 2 to 3 weeks in the spring. The melt period represents an event when large quantities of water may enter the soil system; the possibilities exist for recharging the groundwater system, or else generating surface runoff. The objective of this study was to determine the magnitude of potential groundwater recharge from snowmelt. Instrumentation was installed and monitored over two winter seasons to quantify the accumulation and ablation of the snowpack. Thermal and moisture data were collected to characterize the snow pack and soil conditions prior to, during, and following the ablation. Lysimeters were installed at various depths to intercept soil water. The volume of potential areal recharge for 1976 was 3.5 cm and for 1977 was 3.0 cm, which represented about 35 per cent of the maximum snowpack content. It is concluded that permafrost-free areas can contribute significantly to groundwater recharge during snowmelt ablation. The work upon which this completion report is based was supported by funds provided by the United States Department of the Interior, Office of Water Research and Technology under the Water Resources Research Act of 1964, Public Law 88379, as amended. Report permafrost Subarctic University of Alaska: ScholarWorks@UA |
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Open Polar |
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University of Alaska: ScholarWorks@UA |
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ftunivalaska |
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unknown |
| description |
The pathways of soil water in cold climates are influenced, in addition to the normal forces, by the presence of permafrost and the temperature gradients in the soil system, whereas the infiltration of surface water into the soil system is a function of moisture levels, soil type and condition of the soil (whether it is frozen or not). Snowfall, with subsequent surface storage over a period of several months, typifies Alaskan winters. This snowfall often accounts for 50 per cent or more of the annual precipitation, with ablation occurring over a time span of 2 to 3 weeks in the spring. The melt period represents an event when large quantities of water may enter the soil system; the possibilities exist for recharging the groundwater system, or else generating surface runoff. The objective of this study was to determine the magnitude of potential groundwater recharge from snowmelt. Instrumentation was installed and monitored over two winter seasons to quantify the accumulation and ablation of the snowpack. Thermal and moisture data were collected to characterize the snow pack and soil conditions prior to, during, and following the ablation. Lysimeters were installed at various depths to intercept soil water. The volume of potential areal recharge for 1976 was 3.5 cm and for 1977 was 3.0 cm, which represented about 35 per cent of the maximum snowpack content. It is concluded that permafrost-free areas can contribute significantly to groundwater recharge during snowmelt ablation. The work upon which this completion report is based was supported by funds provided by the United States Department of the Interior, Office of Water Research and Technology under the Water Resources Research Act of 1964, Public Law 88379, as amended. |
| format |
Report |
| author |
Kane, Douglas L. Seifert, Richard D. Fox, John D. Taylor, George S. |
| spellingShingle |
Kane, Douglas L. Seifert, Richard D. Fox, John D. Taylor, George S. Snowmelt -frozen soil characteristics for a subarctic setting |
| author_facet |
Kane, Douglas L. Seifert, Richard D. Fox, John D. Taylor, George S. |
| author_sort |
Kane, Douglas L. |
| title |
Snowmelt -frozen soil characteristics for a subarctic setting |
| title_short |
Snowmelt -frozen soil characteristics for a subarctic setting |
| title_full |
Snowmelt -frozen soil characteristics for a subarctic setting |
| title_fullStr |
Snowmelt -frozen soil characteristics for a subarctic setting |
| title_full_unstemmed |
Snowmelt -frozen soil characteristics for a subarctic setting |
| title_sort |
snowmelt -frozen soil characteristics for a subarctic setting |
| publisher |
University of Alaska, Institute of Water Resources |
| publishDate |
1978 |
| url |
http://hdl.handle.net/11122/1865 |
| genre |
permafrost Subarctic |
| genre_facet |
permafrost Subarctic |
| op_relation |
IWR;no. 84 http://hdl.handle.net/11122/1865 |
| _version_ |
1766166022778257408 |