Kulessa, B. and Hubbard, B. and Brown, G. H. (2006)
Time-lapse imaging of subglacial drainage conditions using three-dimensional inversion of borehole electrical resistivity data
Article
- Cite key
- Kulessa2006
- Language
- en
- Journal
- Journal of Glaciology
- Volume
- 52
- Number
- 176
- Pages
- 49-57
- Note
- Journal of Glaciology, Vol. 52, No. 176, 2006
- URL
- http://docserver.ingentaconnect.com/deliver/connect/igsoc/00221430/v52n176/s5.pdf?expires=1345731502&id=70163091&titleid=6497&accname=Universite+de+Lausanne&checksum=33D49BFC72A48DB0C79D8359BCA32F16
- Description
- We recorded electrical resistivity data at the base of four boreholes drilled through Haut Glacier d'Arolla, Switzerland. The data were acquired repetitively every hour over two diurnal hydrological cycles in the late melt season, separated by 10 days. Constrained three-dimensional (3-D) data inversion allowed reconstruction of hourly variations in bulk resistivity in the subglacial sediment layer. Inverted resistivity models reflect the establishment of channelized subglacial drainage in the study area between the two hydrological cycles, in agreement with previous work. Daily variations in bulk and water resistivity are in phase, and bulk resistivity amplitudes decrease away from the subglacial channel. Using selected electrical hydraulic relationships, we estimate metre-scale changes in the hydraulic conductivity and porosity of the subglacial sediment layer, accounting for increasing clay content and decreasing median grain radius with distance from the channel. Hydraulic conductivity and porosity were respectively calculated to decrease from (6.4 ± 2.1) 10-2 ms-1 and 0.34 ± 0.01 at the channel to (3.3 ± 2.2) 10-;2 ms-1 and 0.26 ± 0.01 at a distance of 5 m from it. The hydraulic conductivity estimates are in agreement with previously inferred values, and the porosity estimates fall within the expected range for unlithified subglacial sediments. We conclude that collection and inversion of repeat 3-D subglacial resistivity data is feasible and has the capacity to generate multidimensional images of subglacial hydraulic processes and properties.