loading page

The Frictional-Viscous Transition in Experimentally Deformed Granitoid Fault Gouge
  • +3
  • Weijia Zhan,
  • André Niemeijer,
  • Alfons Berger,
  • Natalia Nevskaya,
  • Christopher James Spiers,
  • Marco Herwegh
Weijia Zhan
University of Bern

Corresponding Author:[email protected]

Author Profile
André Niemeijer
Utrecht University
Author Profile
Alfons Berger
University of Bern
Author Profile
Natalia Nevskaya
University of Bern
Author Profile
Christopher James Spiers
Utrecht University
Author Profile
Marco Herwegh
University of Bern
Author Profile

Abstract

In crustal faults dominated by granitoid gouges, the frictional-viscous transition marks a significant change in strength constraining the lower depth limit of the seismogenic zone. Dissolution-precipitation creep (DPC) may play an important role in initiating this transition, especially within polymineralic materials. Yet, it remains unclear to what extent DPC contributes to the weakening of granitoid gouge materials at the transition. Here we conducted sliding experiments on wet granitoid gouges to large displacement (15 mm), at an effective normal stress and pore fluid pressure of 100 MPa, at temperatures of 20-650°C, and at sliding velocities of 0.1-100 μm/s, which are relevant for earthquake nucleation. Gouge shear strengths were generally ~75 MPa even at temperatures up to 650°C and at velocities > 1 mm/s. At velocities ≤ 1 mm/s, strengths decreased at temperatures ≥ 450°C, reaching a minimum of 37 MPa at the highest temperature and lowest velocity condition. Microstructural observations showed that, as the gouges weakened, the strain localized into thin, dense, and ultrafine-grained (≤ 1 μm) principal slip zones, where nanopores were located along grain contacts and contained minute biotite-quartz-feldspar precipitates. Though poorly constrained, the stress sensitivity exponent n decreased from ≥17 at 20°C to ~2 at 650°C at the lowest velocities. These findings suggest that high temperature, slow velocity and/or small grain sizes promote DPC-accommodated granular flow over cataclastic frictional granular flow, leading to the observed weakening and strain localization. Field observations together with extrapolation suggest that DPC-induced weakening occurs at depths of 7-20 km depending on geothermal gradient.
27 Jan 2024Submitted to ESS Open Archive
02 Feb 2024Published in ESS Open Archive
Aug 2024Published in Journal of Geophysical Research: Solid Earth volume 129 issue 8. https://doi.org/10.1029/2024JB028797