The 2002 rock/ice avalanche at Kolka/Karmadon, Russian Caucasus: assessment of extraordinary avalanche formation and mobility, and application of QuickBird satellite imagery

Huggel, Christian; Zgraggen-Oswald, S.; Haeberli, Wilfried; Kääb, Andreas; Polkvoj, A.; Galushkin, I.; Evans, Stephen G.

doi:10.5194/nhess-5-173-2005

Cited by 265 publications

(210 citation statements)

References 37 publications

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“…The main part of the glacier detached during a major rock avalanche and cascaded down the valley for a total distance of ∼ 20 km, at which point a mudflow was generated flowing a further 15-17 km downstream. The average velocity of the main flow is thought to have been close to 50 m s −1 (180 km h −1 ) (Petrakov et al, 2008) with maximum velocity estimates ranging from 70 m s −1 (250 km h −1 ) (Drobyshev, 2006) to 90 m s −1 (325 km h −1 ) (Huggel et al, 2005). Until this event collapse of an entire valley-type glacier had not been considered possible.…”

Section: Catastrophic Glacier Multi-phase Mass Movementmentioning

confidence: 99%

“…They involve collapse of all or part of a glacier due to significant rock avalanching and involve extraordinary velocities, long-distance run-outs, and superelevations (Petrakov et al, 2008). From the few examples studied, they begin as rock and/or ice avalanches/slides before gradually transforming into ultra-high speed flows (> 30 ms −1 ) and often finish as debris flows (Huggel et al, 2005;Petrakov et al, 2008). They can travel for distances of tens of kilometres (Huggel et al, 2005;Petrakov et al, 2008).…”

Section: Catastrophic Glacier Multi-phase Mass Movementmentioning

confidence: 99%

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Review Article: Potential geomorphic consequences of a future great (Mw = 8.0+) Alpine Fault earthquake, South Island, New Zealand

Robinson

Davies

2013

Nat. Hazards Earth Syst. Sci.

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Abstract. The Alpine Fault in New Zealand's South Island has not sustained a large magnitude earthquake since ca. AD 1717. The time since this rupture is close to the average inferred recurrence interval of the fault (∼ 300 yr). The Alpine Fault is therefore expected to generate a large magnitude earthquake in the near future. Previous ruptures of this fault are inferred to have generated M w = 8.0 or greater earthquakes and to have resulted in, amongst other geomorphic hazards, large-scale landslides and landslide dams throughout the Southern Alps. There is currently 85 % probability that the Alpine Fault will cause a M w = 8.0+ earthquake within the next 100 yr. While the seismic hazard is fairly well understood, that of the consequential geomorphic activity is less well studied, and these consequences are explored herein. They are expected to include landsliding, landslide damming, dam-break flooding, debris flows, river aggradation, liquefaction, and landslidegenerated lake/fiord tsunami. Using evidence from previous events within New Zealand as well as analogous international examples, we develop first-order estimates of the likely magnitude and possible locations of the geomorphic effects associated with earthquakes. Landsliding is expected to affect an area > 30 000 km 2 and involve > 1 billion m 3 of material. Some tens of landslide dams are expected to occur in narrow, steep-sided gorges in the affected region. Debris flows will be generated in the first long-duration rainfall after the earthquake and will continue to occur for several years as rainfall (re)mobilises landslide material. In total more than 1000 debris flows are likely to be generated at some time after the earthquake. Aggradation of up to 3 m will cover an area > 125 km 2 and is likely to occur on many West Coast alluvial fans and floodplains. The impact of these effects will be felt across the entire South Island and is likely to continue for several decades.

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Section: Catastrophic Glacier Multi-phase Mass Movementmentioning

confidence: 99%

Section: Catastrophic Glacier Multi-phase Mass Movementmentioning

confidence: 99%

Review Article: Potential geomorphic consequences of a future great (Mw = 8.0+) Alpine Fault earthquake, South Island, New Zealand

Robinson

Davies

2013

Nat. Hazards Earth Syst. Sci.

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“…Rock-ice avalanche deposits resemble those of slurry flows 418 in their distal regions (Fig. 10); photos from the Kolka-Karmadon (Huggel et al, 2005) and 419 corresponds to the total volume of the Komansu event, at least 6-10 km 3 of ice would have been 436 required to generate a rock-ice avalanche; correspondingly more would be needed to cause the 437 inferred 5-10 km 3 event into a rock-ice avalanche. It is difficult to explain the availability of such 438 a large volume of ice, especially given that the age of the deposit appears to correspond to a time 439 after the region's glaciers began to retreat.…”

Section: Rock-ice Avalanche 393mentioning

confidence: 99%

The extremely long-runout Komansu rock avalanche in the Trans Alai range, Pamir Mountains, southern Kyrgyzstan

et al. 2014

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The nal publication is available at Springer via http://dx.doi.org/10.1007/s10346-014-0492-y Additional information: Use policyThe full-text may be used and/or reproduced, and given to third parties in any format or medium, without prior permission or charge, for personal research or study, educational, or not-for-pro t purposes provided that:• a full bibliographic reference is made to the original source • a link is made to the metadata record in DRO • the full-text is not changed in any way The full-text must not be sold in any format or medium without the formal permission of the copyright holders.Please consult the full DRO policy for further details. Massive rock avalanches form some of the largest landslide deposits on Earth and are major 16 geohazards in high-relief mountains. This work reinterprets a previously-reported glacial deposit in 17 the Alai Valley of Kyrgyzstan as the result of an extremely long-runout, probably coseismic, rock 18 avalanche from the Komansu River catchment. Total runout of the rock avalanche is ~28 km, 19 making it one of the longest-runout subaerial non-volcanic rock avalanches thus far identified on 20Earth. This runout length appears to require a rock volume of ~20 km 3 ; however the likely source 21 zone in the Trans Alai range likely contained just ~4 km 3 of rock and presently the deposit has a 22 volume of only 3-5 km 3 ; a pure rock avalanche volume of > 10 km 3 is therefore impossible, so the 23 event was much more mobile than most non-volcanic rock avalanches. Explaining this exceptional 24 mobility is crucial for present day hazard analysis. There is unequivocal sedimentary evidence for 25 intense basal fragmentation, and the deposit in the Alai valley has prominent hummocks; these 26 indicate a rock avalanche rather than a rock-ice avalanche origin. The event occurred 5000-11000 yr 27 B.P., after the region's glaciers had begun retreating, implying that supraglacial runout was limited. 28Current volume -runout relationships suggest a maximum runout of ~10 km for a 4 km 3 rock 29 avalanche. Volcanic debris avalanches, however, are more mobile than non-volcanic rock avalanches 30 due to their much higher source water content; a rock avalanche containing a similarly high water 31 content would require a volume of about 8 km 3 to explain the extreme runout of the Komansu event. 32

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“…Barla et al, 2000;Noetzli et al, 2003;Cola, 2005;Oppikofer et al, 2008;Fischer, 2009), Canada and Alaska (e.g. Evans and Clague, 1994;Geertsema et al, 2006), the Caucasus (Huggel et al, 2005) and New Zealand (e.g. Cox and Allen, 2009;Allen et al, 2009).…”

Section: Introductionmentioning

confidence: 99%

Monitoring topographic changes in a periglacial high‐mountain face using high‐resolution DTMs, Monte Rosa East Face, Italian Alps

Fischer

Eisenbeiss

Kääb

et al. 2011

Permafrost & Periglacial

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This paper describes a remote sensing-based approach for detailed topographic investigations in steep periglacial high-mountain faces. The study was conducted at one of the highest periglacial rock faces in the European Alps, the permafrost-affected and partially glacierised east face of Monte Rosa. Strongly increased rock and ice avalanche activity on this rock wall has caused major topographic change in recent decades. A time series of high-resolution digital terrain models (DTMs) with a 2-m resolution was produced from digital aerial photogrammetry for 1956, 1988 and 2001 and from airborne LiDAR for 2005 and 2007. The DTM comparisons reveal a total volume loss of permafrost-affected bedrock and glacier ice of more than 20 Â 10 6 m 3 over the past 50 years, with the majority of the loss since 1988. Analysis of all unstable areas and detachment zones showed that the sequence of the main slope failures is spatially connected and that there is coupling between permafrost bedrock instability and the condition of adjacent hanging glaciers.

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The 2002 rock/ice avalanche at Kolka/Karmadon, Russian Caucasus: assessment of extraordinary avalanche formation and mobility, and application of QuickBird satellite imagery

Cited by 265 publications

References 37 publications

Review Article: Potential geomorphic consequences of a future great (<i>M</i><sub>w</sub> = 8.0+) Alpine Fault earthquake, South Island, New Zealand

Review Article: Potential geomorphic consequences of a future great (<i>M</i><sub>w</sub> = 8.0+) Alpine Fault earthquake, South Island, New Zealand

The extremely long-runout Komansu rock avalanche in the Trans Alai range, Pamir Mountains, southern Kyrgyzstan

Monitoring topographic changes in a periglacial high‐mountain face using high‐resolution DTMs, Monte Rosa East Face, Italian Alps

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The 2002 rock/ice avalanche at Kolka/Karmadon, Russian Caucasus: assessment of extraordinary avalanche formation and mobility, and application of QuickBird satellite imagery

Cited by 265 publications

References 37 publications

Review Article: Potential geomorphic consequences of a future great (&lt;i&gt;M&lt;/i&gt;&lt;sub&gt;w&lt;/sub&gt; = 8.0+) Alpine Fault earthquake, South Island, New Zealand

Review Article: Potential geomorphic consequences of a future great (&lt;i&gt;M&lt;/i&gt;&lt;sub&gt;w&lt;/sub&gt; = 8.0+) Alpine Fault earthquake, South Island, New Zealand

The extremely long-runout Komansu rock avalanche in the Trans Alai range, Pamir Mountains, southern Kyrgyzstan

Monitoring topographic changes in a periglacial high‐mountain face using high‐resolution DTMs, Monte Rosa East Face, Italian Alps

Contact Info

Product

Resources

About

Review Article: Potential geomorphic consequences of a future great (<i>M</i><sub>w</sub> = 8.0+) Alpine Fault earthquake, South Island, New Zealand

Review Article: Potential geomorphic consequences of a future great (<i>M</i><sub>w</sub> = 8.0+) Alpine Fault earthquake, South Island, New Zealand