Geology, glacier retreat and permafrost degradation as controlling factors of slope instabilities in a high-mountain rock wall: the Monte Rosa east face

Fischer, Luzia; Kääb, Andreas; Huggel, Christian; Noetzli, Jeannette

doi:10.5194/nhess-6-761-2006

Cited by 205 publications

(165 citation statements)

References 14 publications

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“…The east face of Monte Rosa extends from about 2200 m to over 4600 m a.s.l., and was the site of two spectacular avalanches in 2005 and 2007 (Fischer et al 2006). The slope increases upward, reaching greater than 55 • in the exposed gneissic bedrock sections and greater than 40 • in the sections with glaciers (figure 12).…”

Section: (C) Monte Rosa Alpsmentioning

confidence: 99%

“…Studies based on sequential historical photographs have shown that the ice cover on the east face of the mountain changed a little during the twentieth century until about 1980, when it began to rapidly decrease (Haeberli et al 2002;Fischer et al submitted b). Slope instability involving both ice and rock increased around 1990 and has continued to the present (Fischer et al 2006 The 2005 event was a large ice avalanche (1.1 × 10 6 m 3 ) that initiated from a steep glacier terminating at 3500 m a.s.l. and reached the foot of the face, where a large supraglacial lake had formed in 2002, but had drained in 2003 (figure 12).…”

Section: (C) Monte Rosa Alpsmentioning

confidence: 99%

“…Previous studies show that the lower limit of permafrost is at about 3000 m a.s.l. on north-to northeast-facing slopes, and up to 500 m higher on east-facing sections (Zgraggen 2005;Fischer et al 2006;Huggel 2009). …”

Section: (C) Monte Rosa Alpsmentioning

confidence: 99%

“…Indications of possible effects of climate change on slope stability has come from an increasing number of large-size rock falls and rock avalanches from permafrost areas in the Alps over the past two decades (Barla et al 2000;Fischer et al 2006;Fischer & Huggel 2008;Sosio et al 2008). Many of these events have not yet been studied in detail, and the causes and trigger processes are not adequately understood.…”

Section: Introductionmentioning

confidence: 99%

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Recent and future warm extreme events and high-mountain slope stability

Huggel

Salzmann

Allen

et al. 2010

Phil. Trans. R. Soc. A.

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163

123

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The number of large slope failures in some high-mountain regions such as the European Alps has increased during the past two to three decades. There is concern that recent climate change is driving this increase in slope failures, thus possibly further exacerbating the hazard in the future. Although the effects of a gradual temperature rise on glaciers and permafrost have been extensively studied, the impacts of short-term, unusually warm temperature increases on slope stability in high mountains remain largely unexplored.We describe several large slope failures in rock and ice in recent years in Alaska, New Zealand and the European Alps, and analyse weather patterns in the days and weeks before the failures. Although we did not find one general temperature pattern, all the failures were preceded by unusually warm periods; some happened immediately after temperatures suddenly dropped to freezing.We assessed the frequency of warm extremes in the future by analysing eight regional climate models from the recently completed European Union programme ENSEMBLES for the central Swiss Alps. The models show an increase in the higher frequency of high-temperature events for the period 2001-2050 compared with a 1951-2000 reference period. Warm events lasting 5, 10 and 30 days are projected to increase by about 1.5-4 times by 2050 and in some models by up to 10 times.Warm extremes can trigger large landslides in temperature-sensitive high mountains by enhancing the production of water by melt of snow and ice, and by rapid thaw. Although these processes reduce slope strength, they must be considered within the local geological, glaciological and topographic context of a slope.

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Section: (C) Monte Rosa Alpsmentioning

confidence: 99%

Section: (C) Monte Rosa Alpsmentioning

confidence: 99%

Section: (C) Monte Rosa Alpsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Recent and future warm extreme events and high-mountain slope stability

Huggel

Salzmann

Allen

et al. 2010

Phil. Trans. R. Soc. A.

Self Cite

163

123

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show abstract

“…The possibility that failure was triggered by warming of ice in bedrock joints reducing the stability of the rock mass (e.g. Dramis et al, 1995;Haeberli et al, 1997;Davies et al, 2001;Fischer et al, 2006;Gruber and Haeberli, 2007) seems unlikely as failure occurred during cold periods associated with widespread permafrost, but cannot be excluded owing to the low precision of the exposure ages.…”

Section: Paraglacial Landscape Modificationmentioning

confidence: 99%

Exposure dating and reinterpretation of coarse debris accumulations (‘rock glaciers’) in the Cairngorm Mountains, Scotland

Ballantyne

Schnabel

2008

J Quaternary Science

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Relict rock glaciers have considerable potential for contributing to palaeoclimatic reconstruction, but this potential is often undermined by lack of dating control and problems of interpretation. Here we reinvestigate and date four proposed 'rock glaciers' in the Cairngorm Mountains and show that the morphology of only one of these appears consistent with that of a true rock glacier produced by creep of underlying ice or ice-rich sediment. All four features comprise rockslide or rock avalanche runout debris, and the possibility that all four represent unmodified runout accumulations cannot be discounted. Surface exposure dating of the four debris accumulations using cosmogenic 10 Be produced uncertainty-weighted mean ages of 15.4 AE 0.8 ka, 16.2 AE 1.0 ka, 12.1 AE 0.6 ka and 12.7 AE 0.8 ka. All four ages imply emplacement under cold stadial conditions, two prior to the Windermere Interstade of ca. 14.5-12.9 cal. ka BP and two during the Loch Lomond Stade of ca. 12.9-11.5 cal. ka BP. The above ages indicate that paraglacial rock-slope failure on granite rockwalls occurred within a few millennia after deglaciation. The mean exposure ages obtained for runout debris at two sites -Strath Nethy (16.2 AE 1.0 ka) and Lairig Ghru (15.4 AE 0.8 ka) -are consistent with basal radiocarbon ages from Loch Etteridge, 22 km to the southwest (mean ¼ 15.6 AE 0.3 cal. ka BP) and imply widespread deglaciation of the Cairngorms and adjacent valleys before 15 ka and possibly 16 ka.

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Determination of warm, sensitive permafrost areas in near‐vertical rockwalls and evaluation of distributed models by electrical resistivity tomography

et al. 2015

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Alpine rockwalls with warm permafrost (near 0°C) are the most active rockfall detachment zones in the Mont Blanc massif (MBM, French Alps) with more than 380 recent events. Near-vertical rockwall permafrost is spatially controlled by variations in rock fractures, snow cover, and microtopography. A reliable method to validate the distribution of permafrost in critical and unstable areas does not yet exist. We present seven electrical resistivity tomography (ERT) surveys measured on five near-vertical rockwalls in the MBM from 2012 and 2013 that have been calibrated with measurements on a granite sample in the laboratory. ERT shows consistent measurements of remaining sensitive permafrost relating to inferred temperatures from 0 to À1.5°C. ERT results demonstrate evidence of topographic controls on permafrost distribution and resistivity gradients that appear to reflect crest width. ERT results are compared to two permafrost index maps that use topoclimatic factors and combine effects of thin snow and fractures, where index model spatial resolution is crucial for the validation with ERT. In cryospheric environments, index maps seem to overestimate permafrost conditions in glacial environments. As a consequence, the sensitive areas of permafrost may slightly deviate from the results from distributed models that are only constrained by topoclimatic factors and interpreted with consideration of local fracture and snow conditions. This study demonstrates (i) that the sensitive and hazardous areas of permafrost in near-vertical rock faces can be assessed and monitored by the means of temperature-calibrated ERT and (ii) that ERT can be used for distributed model validation.

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Geology, glacier retreat and permafrost degradation as controlling factors of slope instabilities in a high-mountain rock wall: the Monte Rosa east face

Cited by 205 publications

References 14 publications

Recent and future warm extreme events and high-mountain slope stability

Recent and future warm extreme events and high-mountain slope stability

Exposure dating and reinterpretation of coarse debris accumulations (‘rock glaciers’) in the Cairngorm Mountains, Scotland

Determination of warm, sensitive permafrost areas in near‐vertical rockwalls and evaluation of distributed models by electrical resistivity tomography

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