Evidence of frost-cracking inferred from acoustic emissions in a high-alpine rock-wall

Ice formation within rock is known to be an important driver of near-surface frost weathering as well as of rock damage at the depth of several meters, which may play a crucial role for the slow preconditioning of rock fall in steep permafrost areas. This letter reports results from an experiment wh...

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Bibliographic Details
Published in:Earth and Planetary Science Letters
Main Authors: Amitrano, D. (D.), Gruber, S. (Stephan), Girard, L. (L.)
Format: Article in Journal/Newspaper
Language:English
Published: 2012
Subjects:
Acoustic emission
Frost-cracking
Mechanical weathering
Scaling properties
Ice
permafrost
Online Access:https://ir.library.carleton.ca/pub/19154
https://doi.org/10.1016/j.epsl.2012.06.014
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Summary:Ice formation within rock is known to be an important driver of near-surface frost weathering as well as of rock damage at the depth of several meters, which may play a crucial role for the slow preconditioning of rock fall in steep permafrost areas. This letter reports results from an experiment where acoustic emission monitoring was used to investigate rock damage in a high-alpine rock-wall induced by natural thermal cycling and freezing/thawing. The analysis of the large catalog of events obtained shows (i) robust power-law distributions in the time and energy domains, a footprint of rock micro-fracturing activity induced by stresses arising from thermal variations and associated freezing/thawing of rock; (ii) an increase in AE activity under sub-zero rock-temperatures, suggesting the importance of freezing-induced stresses. AE activity further increases in locations of the rock-wall that are prone to receiving melt water. These results suggest that the framework of further modeling studies (theoretical and numerical) should include damage, elastic interaction and poro-mechanics in order to describe freezing-related stresses.

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