Postglacial erosion of bedrock surfaces and deglaciation timing; new insights from the Mont Blanc Massif (Western Alps)

Since the Last Glacial Maximum, ∼20 k.y. ago, Alpine glaciers have retreated and thinned. This transition exposed bare bedrock surfaces that could then be eroded by a combination of debuttressing or local frost cracking and weathering. Quantification of the respective contributions of these processe...

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Bibliographic Details
Published in:Geology (Boulder) 2020-02, Vol.48 (2), p.139-144
Main Authors: Lehmann, Benjamin, Herman, Frédéric, Valla, Pierre G, King, Georgina E, Biswas, Rabiul H, Ivy-Ochs, Susan, Steinemann, Olivia, Christl, Marcus
Format: Article
Language:English
Subjects:
alkaline earth metals
Alps
Be-10
Bedrock
beryllium
Cenozoic
Deglaciation
Elevation
Environmental Sciences
erosion
Erosion control
Erosion rates
Europe
Exposure
exposure age
France
Geochronology
Geology
glacial erosion
Glacial periods
Glacier retreat
Glaciers
isotopes
Last Glacial Maximum
Massifs
Meltwater
metals
Mont Blanc
Morphometry
Mountain climates
Mountain glaciers
Mountains
optically stimulated luminescence
Quaternary
Quaternary geology
radioactive isotopes
relative age
Snow cover
Spatial variations
upper Quaternary
Valleys
Water surface slope
Weathering
Western Alps
Western Europe
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Summary:Since the Last Glacial Maximum, ∼20 k.y. ago, Alpine glaciers have retreated and thinned. This transition exposed bare bedrock surfaces that could then be eroded by a combination of debuttressing or local frost cracking and weathering. Quantification of the respective contributions of these processes is necessary to understand the links between long-term climate and erosion in mountains. Here, we quantified the erosion histories of postglacial exposed bedrock in glacial valleys. Combining optically stimulated luminescence and terrestrial cosmogenic nuclide (TCN) surface exposure dating, we estimated the erosion rate of bedrock surfaces at time scales from 101 to 104 yr. Bedrock surfaces sampled from the flanks of the Mer de Glace (Mont Blanc massif, European Alps) revealed erosion rates that vary from 3.5 ± 1.2 × 10-3 mm/yr to 4.3 ± 0.6 mm/yr over ∼500 m of elevation, with a negative correlation between erosion rate and elevation. The observed spatial variation in erosion rates, and their high values, reflect morphometric (elevation and surface slope) and climatic (temperature and snow cover) controls. Furthermore, the derived erosion rates can be used to correct the timing of deglaciation based on TCN data, potentially suggesting very rapid ice thinning during the Gschnitz stadial.
ISSN:0091-7613
1943-2682
DOI:10.1130/G46585.1