The largest rock avalanches in Patagonia: Timing and relation to Patagonian Ice Sheet retreat

One of the largest concentrations of giant landslides (≥108 m3) in Patagonia is in the eastern part of Lago Cochrane/Pueyrredón (LP) valley in Argentina. In addition to minor earthflows and rock slides, this landslide cluster is dominated by rock and debris avalanches that affect the northern slope...

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Bibliographic Details
Published in:Quaternary Science Reviews
Main Authors: Pánek, Tomáš, Břežný, Michal, Smedley, Rachel, Winocur, Diego, Schönfeldt, Elisabeth, Agliardi, Federico, Fenn, Kaja
Format: Article in Journal/Newspaper
Language:English
Published: Elsevier BV 2023
Subjects:
Patagonia
Argentina
Glacial Lake
Belgrano
Low Rock
Ice Sheet
Online Access:http://livrepository.liverpool.ac.uk/3167771/
https://doi.org/10.1016/j.quascirev.2023.107962
http://livrepository.liverpool.ac.uk/3167771/1/JQSR-D-22-00604_R.pdf
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Summary:One of the largest concentrations of giant landslides (≥108 m3) in Patagonia is in the eastern part of Lago Cochrane/Pueyrredón (LP) valley in Argentina. In addition to minor earthflows and rock slides, this landslide cluster is dominated by rock and debris avalanches that affect the northern slope of Meseta Belgrano, the largest of which have volumes >1 km3 and a runout of >10 km. To determine the chronology of these large landslides and their relationship to the geological setting and the glacial history related to the Last Glacial Maximum (LGM) ∼20–18 ka ago, we combined geomorphological mapping with absolute dating (luminescence and radiocarbon dating) and numerical modelling of slope stability. Dating and cross-cutting relationships with glaciolacustrine deposits suggest that some of the largest rock avalanches collapsed directly into a glacial lake between ∼17 and ∼12 ka, soon after deglaciation, but some were pre-glacial and landslide activity continued until today, posing a potential hazard to the area. In agreement with these data, numerical modelling suggests that slope stability was only marginally affected by ice retreat and glacial lake drainage, and landslides were most likely favoured by relatively low rock strength, related glacially-conditioned topography, and, possibly, seismic activity. A newly identified active fault at the base of the Meseta Belgrano, whose activity was likely enhanced by postglacial rebound, was probably the key factor that concentrated postglacial rock avalanches into the LP valley. We conclude that exceptionally large (km-scale) landslides can occur on slopes made of relatively weak rocks in a glacially-conditioned topographic setting even without a strong direct triggering effect of deglaciation, while fatigue due to long-term seismicity may promote collapse.

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