Abstract
Highly localized slip zones, seen within ductile shear zones developed in nature, such as pseudotachylite bands occurring within mylonites, are widely recognized as evidence for earthquake nucleation and/or propagation within the ductile regime. To understand brittle/frictional localization processes in ductile shear zones and to relate these to earthquake nucleation and propagation, we performed large velocity step-change tests on a brine-saturated, 80:20 (wt.%) mixture of halite and muscovite gouge after forming a mature mylonitic structure through frictional-viscous flow. The direct effect a on shear strength that occurs in response to an instantaneous upward velocity-step is an important parameter in determining the potential for, and nature of, seismic rupture nucleation and propagation. We obtained reproducible results regarding low velocity mechanical behavior compared with previous work, but also obtained new insights into effects of sudden increases in slip velocity on localization and strength evolution, at velocities above a critical velocity Vc (~20 μm/s). We found that once a ductile, mylonitic structure has developed in a shear zone, subsequent cataclastic deformation is consistently localized in a narrow zone. This switch to localized deformation is controlled by the imposed velocity, and becomes most apparent at velocities above Vc. In addition, the direct effect drops rapidly when the velocity exceeds Vc. This implies that slip can accelerate towards seismic velocities almost instantly and without much loss of energy, once Vc is exceeded. Obtaining a measure for Vc in natural faults is therefore of key importance for understanding earthquake nucleation and propagation in the brittle-ductile transitional regime.
Original language | English |
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Pages (from-to) | 513-530 |
Number of pages | 8 |
Journal | Geochemistry, Geophysics, Geosystems |
Volume | 18 |
Issue number | 2 |
DOIs | |
Publication status | Published - Feb 2017 |
Keywords
- brittle-ductile transition
- localization
- mylonitic microstructure
- direct effect
- critical velocity