TY - JOUR
T1 - Seasonally intermittent water flow through deep fractures in an Alpine Rock Ridge
T2 - Gemsstock, Central Swiss Alps
AU - Phillips, Marcia
AU - Haberkorn, Anna
AU - Draebing, Daniel
AU - Krautblatter, Michael
AU - Rhyner, Hansueli
AU - Kenner, Robert
N1 - Publisher Copyright:
© 2016 Elsevier B.V.
PY - 2016/5/1
Y1 - 2016/5/1
N2 - Geological investigations and seismic refraction tomography reveal a series of 70° steep, parallel and continuous fractures at 2950 m asl within the Gemsstock rock ridge (Central Swiss Alps), at the lower fringe of alpine permafrost. Temperature measurements in a 40 m horizontal borehole through the base of the ridge show that whilst conductive heat transfer dominates within the rock mass, brief negative and positive temperature anomalies are registered in summer. These have very small amplitudes and coincide with summer rainfall events lasting longer than 12 h. In contrast, a complete lack of anomalous thermal signals during spring snowmelt suggests that runoff does not penetrate the open joints, despite high snow water equivalents of around 400 mm. This is attributed to the development of an approximately 20 cm thick, continuous and impermeable basal ice layer which forms at the interface between the snow cover and the cold rock on the shady North facing rock wall during snowmelt. Spring snowmelt water therefore does not affect rock temperatures in the centre of the rock mass, despite the presence of deep open joints. The mechanical impact of snowmelt infiltration on rock wall stability at depth is thus assumed to be negligible at this site.
AB - Geological investigations and seismic refraction tomography reveal a series of 70° steep, parallel and continuous fractures at 2950 m asl within the Gemsstock rock ridge (Central Swiss Alps), at the lower fringe of alpine permafrost. Temperature measurements in a 40 m horizontal borehole through the base of the ridge show that whilst conductive heat transfer dominates within the rock mass, brief negative and positive temperature anomalies are registered in summer. These have very small amplitudes and coincide with summer rainfall events lasting longer than 12 h. In contrast, a complete lack of anomalous thermal signals during spring snowmelt suggests that runoff does not penetrate the open joints, despite high snow water equivalents of around 400 mm. This is attributed to the development of an approximately 20 cm thick, continuous and impermeable basal ice layer which forms at the interface between the snow cover and the cold rock on the shady North facing rock wall during snowmelt. Spring snowmelt water therefore does not affect rock temperatures in the centre of the rock mass, despite the presence of deep open joints. The mechanical impact of snowmelt infiltration on rock wall stability at depth is thus assumed to be negligible at this site.
KW - Basal ice layer
KW - Rainwater infiltration
KW - Rock joints
KW - Rock temperature
KW - Rock wall stability
KW - Snowmelt
UR - http://www.scopus.com/inward/record.url?scp=84959298275&partnerID=8YFLogxK
U2 - 10.1016/j.coldregions.2016.02.010
DO - 10.1016/j.coldregions.2016.02.010
M3 - Article
AN - SCOPUS:84959298275
SN - 0165-232X
VL - 125
SP - 117
EP - 127
JO - Cold Regions Science and Technology
JF - Cold Regions Science and Technology
ER -