Using Borehole Temperatures for Knowledge Transfer about Mountain Permafrost: The Example of the 35-year Time Series at Murtèl-Corvatsch (Swiss Alps)

Climate-related permafrost is widespread in cold mountains and heavily affects slope stability. As a subsurface phenomenon, however, it is often still absent in the perception of key partners concerning the discussion and anticipation of long-term impacts on high mountain regions from continued glob...

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Bibliographic Details
Published in:Revue de géographie alpine
Main Authors: Wilfried Haeberli, Jeannette Noetzli, Daniel Vonder Mühll
Format: Article in Journal/Newspaper
Language:English
French
Published: Institut de Géographie Alpine 2023
Subjects:
permafrost
mountains
climate change
borehole temperature
slope stability
Geography. Anthropology. Recreation
G
Physical geography
GB3-5030
Ice
Online Access:https://doi.org/10.4000/rga.11950
https://doaj.org/article/ba34032098f44556b5259ad29acbf39f
Description
Summary:Climate-related permafrost is widespread in cold mountains and heavily affects slope stability. As a subsurface phenomenon, however, it is often still absent in the perception of key partners concerning the discussion and anticipation of long-term impacts on high mountain regions from continued global warming. Outreach and knowledge transfer, therefore, play a key role. Long-term observations of permafrost temperatures measured in boreholes can be used to convey answers and key messages concerning thermal conditions in a spatio-temporal context, related environmental conditions, affected depth ranges, and impacts of warming and degradation on slope stability.The 35-year Murtèl-Corvatsch time series of borehole temperatures from which data is available since 1987, is used here as an example. Today, mountain permafrost is well documented and understood regarding involved processes, as well as its occurrence in space and evolution in time. Thermal anomalies caused by global warming already now reach about 100 meters depth, thereby reducing the ground ice content, causing accelerated creep of ice-rich frozen talus/debris (so-called “rock glaciers”) and reducing the stability of large frozen bedrock masses at steep icy faces and peaks.

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