Characterization and monitoring of the Furggwanghorn rock glacier, Turtmann Valley, Switzerland; results from 2010 to 2012

Climate effects relating to air temperature, radiation, snow cover, and rainfall combine with thaw and infiltration processes to cause changes in the thermal response and associated creep deformations in rock glaciers, which are the geomorphological expression of Alpine permafrost. The annual surfac...

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Published inVadose zone journal Vol. 12; no. 1; pp. 1 - 15
Main Authors Buchli, Thomas, Merz, Kaspar, Zhou, Xiaohai, Kinzelbach, Wolfgang, Springman, Sarah M
Format Journal Article
LanguageEnglish
Published Soil Science Society of America 01.02.2013
The Soil Science Society of America, Inc
Subjects
Alps
boreholes
Central Europe
dye tracers
Europe
faults
field studies
Furggwanghorn
geophysical methods
geophysical surveys
glacial geology
glaciers
granulometry
ground-penetrating radar
Hydrogeology
modern
monitoring
movement
permafrost
permeability
Quaternary geology
radar methods
rock glaciers
seepage
seismic methods
shear zones
surveys
Swiss Alps
Switzerland
Turtmann Valley
unsaturated zone
Valais Switzerland
velocity
water
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Summary:Climate effects relating to air temperature, radiation, snow cover, and rainfall combine with thaw and infiltration processes to cause changes in the thermal response and associated creep deformations in rock glaciers, which are the geomorphological expression of Alpine permafrost. The annual surface creep of some rock glaciers has accelerated recently by an order of magnitude. A multidisciplinary field study links characterization, monitoring, and modeling for such a rock glacier in the Turtmann valley in Switzerland. The first phase consisted of characterization using seismic refraction and ground-penetrating radar (GPR), as well as borehole information and monitoring of meteorological, hydrothermal, and geotechnical variables over 2 yr. The ground model confirmed the heterogeneity of the internal structure, with rock glacier topography affecting the thermal distribution in boreholes and seepage flows from tracer tests at between 10 and 40 m h-1. Temperatures were generally warmer than -0.25°C in the permafrost zone, with some variability in terms of thermal degradation of some layers to 0°C and an active layer of about 3 to 5 m depth. Unique internal shear movements were measured by an automatic inclinometer, which indicated downslope creep rates in the shear zone and at the surface of about 2.4 and 3.2 m yr-1 respectively, which could not be directly linked to temperature at the same depth. These rock glaciers have potential for future instability, which could damage infrastructure in the valley below. It is essential to understand why they have accelerated over the past decade through the complex interactions that have controlled the thermo-hydromechanical response.
Bibliography:Thermal degradation of some rock glaciers in the Turtmann valley (CH) has accelerated recently, causing unusual thermokarst features to develop, with surface creep rates exceeding 3 m/a. A multidisciplinary research project was started to investigate the internal thermal, mechanical, and hydrological interactions affecting this response. The creep velocities with depth show some seasonal dependency.
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ISSN:1539-1663
1539-1663
DOI:10.2136/vzj2012.0067