Title | A remote sensing approach to determine the day-time clear-sky radiation field of a mountain glacier environment: The Athabasca Glacier Basin |
Publication Type | Thesis |
Year of Publication | 1991 |
Authors | Gratton, D. J. |
Volume | Geography |
Issue | Ph. D. |
Pagination | 210 |
Place Published | University of Waterloo |
Publication Language | en |
Abstract | An accurate evaluation of glacier energy balance requires a precise knowledge of surface-cover albedo and emittance. Usually, these values are acquired from field measurements. However, the microclimatological effects in mountainous terrain greatly limit potential for spatial extrapolation of such a set of values. This study overcomes this problem by using the upward radiance values registered on Landsat-5 Thematic Mapper (TM) images and information on the geometry of the terrain extracted from a digital elevation model (DEM). Studies were performed in the Athabasca Glacier basin, one of the major glacier outlets of the Columbia Icefield in the Canadian Rocky Mountains. The methodology is composed, first, of an automated procedure for the physiographic description of the glacierized basin (cover type, elevation, slope, aspect, horizon profiles, sky-view factor, and the level of enclosing topography) in order to calculate the effects of topography on the radiation balance for each 30 m pixel. Because glacier surface covers usually have high reflective behaviours or distinct emission patterns, this study puts special emphasis on modelling the amount of terrain-reflected or terrain-emitted radiation received on a particular surface. Second, the topographic correction is applied to values of irradiance computed using the LOWTRAN-6 code, a spectrally based radiative transfer model, and atmospheric radiosonde measurements of the vertical temperature, air pressure and relative humidity profiles. The measured upward radiance values from TM, corrected for path effects, are used to calculate surface-cover albedo and brightness temperature. Third, the daily net radiation field for snow and ice covers is computed to illustrate the contribution of the estimated surface radiative parameters to the glacier snow and ice melt analysis. The results show that the irradiance values are accurately modelled within 10% of the radiation values acquired from a field pyranometer. The calculated glacial surface-cover reflectance and albedo values compare favourably to published information while the measured surface brightness temperature is well within the expected value range. The snow- and ice-melt translated into predicted runoff rate values underestimate by only 7% the daily average hydrometric gauging station measured value. |
URL | http://search.proquest.com/docview/303977904 |
Topics | Geography |
Locational Keywords | Athabasca Glacier |
Active Link | |
Group | Science |
Citation Key | 37774 |