Evaluation of the energy-based runoff concept for a subalpine tundra hillslope
A major challenge to cold regions hydrology and northern water resources management lies in predicting runoff dynamically in the context of warming-induced changes to the rates and patterns of ground thaw and drainage. Meeting this challenge requires new knowledge of the mechanisms and rates of grou...
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| Format: | Master Thesis |
| Language: | English |
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University of Waterloo
2012
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| Online Access: | http://hdl.handle.net/10012/7135 |
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ftunivwaterloo:oai:uwspace.uwaterloo.ca:10012/7135 |
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ftunivwaterloo:oai:uwspace.uwaterloo.ca:10012/7135 2023-05-15T18:40:44+02:00 Evaluation of the energy-based runoff concept for a subalpine tundra hillslope Che, Qian 2012 http://hdl.handle.net/10012/7135 en eng University of Waterloo http://hdl.handle.net/10012/7135 hillslope hydrology water and energy flow soil thaw preferential flow frost table topography Civil Engineering Master Thesis 2012 ftunivwaterloo 2022-06-18T22:59:34Z A major challenge to cold regions hydrology and northern water resources management lies in predicting runoff dynamically in the context of warming-induced changes to the rates and patterns of ground thaw and drainage. Meeting this challenge requires new knowledge of the mechanisms and rates of ground thaw and their implications to water drainage and storage patterns and processes. The study carries out to evaluate the concept of energy-based runoff in the perspective of ground heat flux, soil thaw and liquid moisture content, tortuosity of snow-free area, preferential flow and discharge of the hillslope. Based on field measurements, coupled energy and water flow is simulated in the Area of Interest (AOI) with a half-hour time interval by the distributed hydrological model, GEOtop. In the field, the saturated hydraulic conductivity varies exponentially between the superficial organic layer and the underlying mineral layer. In the simulation, the parameters of the soil physical properties are input by fourteen uneven layers below the ground surface. Starting from the initially frozen state, the process of soil thaw is simulated with dynamic variables such as soil liquid moisture and ice content, hydraulic conductivity, thermal conductivity and heat capacity. The simulated frost table depths are validated by 44-point measurements and the simulation of point soil temperature is also compared to data measured in an excavated soil pit. As a result, the frost table topography is dominated by both the snow-free pattern and the energy fluxes on the ground surface. The rate and magnitude of runoff derived from snow drift and the ice content of frozen soil is greatly influenced by the frost table topography. According to the simulation, the frost table depth is closely regressed with the ground surface temperature by a power function. As soil thawing progresses, ground heat flux reduces gradually and the rate of soil thaw becomes small when the frost table descends. Along with the snow-free area expanding, the average ... Master Thesis Tundra University of Waterloo, Canada: Institutional Repository |
| institution |
Open Polar |
| collection |
University of Waterloo, Canada: Institutional Repository |
| op_collection_id |
ftunivwaterloo |
| language |
English |
| topic |
hillslope hydrology water and energy flow soil thaw preferential flow frost table topography Civil Engineering |
| spellingShingle |
hillslope hydrology water and energy flow soil thaw preferential flow frost table topography Civil Engineering Che, Qian Evaluation of the energy-based runoff concept for a subalpine tundra hillslope |
| topic_facet |
hillslope hydrology water and energy flow soil thaw preferential flow frost table topography Civil Engineering |
| description |
A major challenge to cold regions hydrology and northern water resources management lies in predicting runoff dynamically in the context of warming-induced changes to the rates and patterns of ground thaw and drainage. Meeting this challenge requires new knowledge of the mechanisms and rates of ground thaw and their implications to water drainage and storage patterns and processes. The study carries out to evaluate the concept of energy-based runoff in the perspective of ground heat flux, soil thaw and liquid moisture content, tortuosity of snow-free area, preferential flow and discharge of the hillslope. Based on field measurements, coupled energy and water flow is simulated in the Area of Interest (AOI) with a half-hour time interval by the distributed hydrological model, GEOtop. In the field, the saturated hydraulic conductivity varies exponentially between the superficial organic layer and the underlying mineral layer. In the simulation, the parameters of the soil physical properties are input by fourteen uneven layers below the ground surface. Starting from the initially frozen state, the process of soil thaw is simulated with dynamic variables such as soil liquid moisture and ice content, hydraulic conductivity, thermal conductivity and heat capacity. The simulated frost table depths are validated by 44-point measurements and the simulation of point soil temperature is also compared to data measured in an excavated soil pit. As a result, the frost table topography is dominated by both the snow-free pattern and the energy fluxes on the ground surface. The rate and magnitude of runoff derived from snow drift and the ice content of frozen soil is greatly influenced by the frost table topography. According to the simulation, the frost table depth is closely regressed with the ground surface temperature by a power function. As soil thawing progresses, ground heat flux reduces gradually and the rate of soil thaw becomes small when the frost table descends. Along with the snow-free area expanding, the average ... |
| format |
Master Thesis |
| author |
Che, Qian |
| author_facet |
Che, Qian |
| author_sort |
Che, Qian |
| title |
Evaluation of the energy-based runoff concept for a subalpine tundra hillslope |
| title_short |
Evaluation of the energy-based runoff concept for a subalpine tundra hillslope |
| title_full |
Evaluation of the energy-based runoff concept for a subalpine tundra hillslope |
| title_fullStr |
Evaluation of the energy-based runoff concept for a subalpine tundra hillslope |
| title_full_unstemmed |
Evaluation of the energy-based runoff concept for a subalpine tundra hillslope |
| title_sort |
evaluation of the energy-based runoff concept for a subalpine tundra hillslope |
| publisher |
University of Waterloo |
| publishDate |
2012 |
| url |
http://hdl.handle.net/10012/7135 |
| genre |
Tundra |
| genre_facet |
Tundra |
| op_relation |
http://hdl.handle.net/10012/7135 |
| _version_ |
1766230146233139200 |