Universal Quake Statistics: From Compressed Nanocrystals to Earthquakes

Universal Quake Statistics: From Compressed Nanocrystals to Earthquakes

Slowly-compressed single crystals, bulk metallic glasses (BMGs), rocks, granular materials and the earth all deform via intermittent slips or “quakes”. We find that although these systems span 12 decades in length scale, they all show the same scaling behavior for their slip size distributions and o...

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Bibliographic Details
Published in:Scientific reports Vol. 5; no. 1; p. 16493
Main Authors: Uhl, Jonathan T., Pathak, Shivesh, Schorlemmer, Danijel, Liu, Xin, Swindeman, Ryan, Brinkman, Braden A. W., LeBlanc, Michael, Tsekenis, Georgios, Friedman, Nir, Behringer, Robert, Denisov, Dmitry, Schall, Peter, Gu, Xiaojun, Wright, Wendelin J., Hufnagel, Todd, Jennings, Andrew, Greer, Julia R., Liaw, P. K., Becker, Thorsten, Dresen, Georg, Dahmen, Karin A.
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 17-11-2015
Nature Publishing Group
Subjects:
639/301/1023/1026
639/301/1023/303
639/301/1034/1039
639/766/530/2804
Crystals
Earthquakes
GEOSCIENCES
Humanities and Social Sciences
Landslides
multidisciplinary
Nanocrystals
Scaling
Science
Seismic activity
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Summary:Slowly-compressed single crystals, bulk metallic glasses (BMGs), rocks, granular materials and the earth all deform via intermittent slips or “quakes”. We find that although these systems span 12 decades in length scale, they all show the same scaling behavior for their slip size distributions and other statistical properties. Remarkably, the size distributions follow the same power law multiplied with the same exponential cutoff. The cutoff grows with applied force for materials spanning length scales from nanometers to kilometers. The tuneability of the cutoff with stress reflects “tuned critical” behavior, rather than self-organized criticality (SOC), which would imply stress-independence. A simple mean field model for avalanches of slipping weak spots explains the agreement across scales. It predicts the observed slip-size distributions and the observed stress-dependent cutoff function. The results enable extrapolations from one scale to another and from one force to another, across different materials and structures, from nanocrystals to earthquakes.
Bibliography:ObjectType-Article-1
SourceType-Scholarly Journals-1
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content type line 23
FE-0011194; FE-0008855
USDOE Office of Fossil Energy (FE)
ISSN:2045-2322
2045-2322
DOI:10.1038/srep16493