TY - JOUR
T1 - Hydrothermal Friction Experiments on Simulated Basaltic Fault Gouge and Implications for Megathrust Earthquakes
AU - Okuda, Hanaya
AU - Niemeijer, André R.
AU - Takahashi, Miki
AU - Yamaguchi, Asuka
AU - Spiers, Christopher J.
N1 - Funding Information:
Comments from two anonymous reviewers are greatly appreciated for improving the clarity of this study. We thank Thony van der Gon Netscher, Gerard Kuijpers, and Floris van Oort (Utrecht University) for technical supports of ring shear apparatus, Yuichi Okuma and Ippei Yamamoto (AORI, University of Tokyo) for the field work at Mugi mélange, and Huiru Lei, Eric Hellebrand, and Oliver Plümper (Utrecht University) for the SEM works. This work benefited from EPOS‐NL Facility Access to Earth Simulation Lab–High Pressure and Temperature lab (ESL‐HPT), supported by the Dutch Research Council (NWO), and from KAKENHI grants (JP20J20413 to H. Okuda; JP19H04621, JP21H01189, and JP21H05202 to A. Yamaguchi). H. Okuda is supported by DC1 fellowship and Overseas Challenge Program for Young Researchers from Japan Society for the Promotion of Science (JSPS).
Funding Information:
Comments from two anonymous reviewers are greatly appreciated for improving the clarity of this study. We thank Thony van der Gon Netscher, Gerard Kuijpers, and Floris van Oort (Utrecht University) for technical supports of ring shear apparatus, Yuichi Okuma and Ippei Yamamoto (AORI, University of Tokyo) for the field work at Mugi mélange, and Huiru Lei, Eric Hellebrand, and Oliver Plümper (Utrecht University) for the SEM works. This work benefited from EPOS-NL Facility Access to Earth Simulation Lab–High Pressure and Temperature lab (ESL-HPT), supported by the Dutch Research Council (NWO), and from KAKENHI grants (JP20J20413 to H. Okuda; JP19H04621, JP21H01189, and JP21H05202 to A. Yamaguchi). H. Okuda is supported by DC1 fellowship and Overseas Challenge Program for Young Researchers from Japan Society for the Promotion of Science (JSPS).
Publisher Copyright:
© 2022. The Authors.
PY - 2023/1
Y1 - 2023/1
N2 - Nucleation of earthquake slip at the plate boundary fault (décollement) in subduction zones has been widely linked to the frictional properties of subducting sedimentary facies. However, recent seismological and geological observations suggest that the décollement develops in the subducting oceanic crust in the depth range of the seismogenic zone, at least in some cases. To understand the frictional properties of oceanic crustal material and their influence on seismogenesis, we performed hydrothermal friction experiments on simulated fault gouges of altered basalt, at temperatures of 100–550°C. The friction coefficient (μ) lies around 0.6 at most temperature conditions but a low μ down to 0.3 was observed at the highest temperature and lowest velocity condition. The velocity dependence of μ, (a−b), changes with increasing temperature from positive to negative at ∼100°C and from negative to positive at ∼450°C. Compared to gouges derived from sedimentary facies, the altered basalt gouge showed potentially unstable velocity weakening over a wider temperature range. Microstructural observations and microphysical interpretation infer that competition between dilatant granular flow and viscous compaction through pressure-solution creep of albite contributed to the observed transition in (a−b). Alteration of oceanic crust during subduction produces fine grains of albite and chlorite through interactions with interstitial water, leading to reduction in its frictional strength and an increase in its seismogenic potential. Therefore, shear deformation possibly localizes within the altered oceanic crust leading to a larger potential for the nucleation of a megathrust earthquake in the depth range of the seismogenic zone.
AB - Nucleation of earthquake slip at the plate boundary fault (décollement) in subduction zones has been widely linked to the frictional properties of subducting sedimentary facies. However, recent seismological and geological observations suggest that the décollement develops in the subducting oceanic crust in the depth range of the seismogenic zone, at least in some cases. To understand the frictional properties of oceanic crustal material and their influence on seismogenesis, we performed hydrothermal friction experiments on simulated fault gouges of altered basalt, at temperatures of 100–550°C. The friction coefficient (μ) lies around 0.6 at most temperature conditions but a low μ down to 0.3 was observed at the highest temperature and lowest velocity condition. The velocity dependence of μ, (a−b), changes with increasing temperature from positive to negative at ∼100°C and from negative to positive at ∼450°C. Compared to gouges derived from sedimentary facies, the altered basalt gouge showed potentially unstable velocity weakening over a wider temperature range. Microstructural observations and microphysical interpretation infer that competition between dilatant granular flow and viscous compaction through pressure-solution creep of albite contributed to the observed transition in (a−b). Alteration of oceanic crust during subduction produces fine grains of albite and chlorite through interactions with interstitial water, leading to reduction in its frictional strength and an increase in its seismogenic potential. Therefore, shear deformation possibly localizes within the altered oceanic crust leading to a larger potential for the nucleation of a megathrust earthquake in the depth range of the seismogenic zone.
KW - altered basalt
KW - friction
KW - hydrothermal conditions
KW - megathrust earthquakes
KW - oceanic crust
KW - subduction zone
UR - http://www.scopus.com/inward/record.url?scp=85147147513&partnerID=8YFLogxK
U2 - 10.1029/2022JB025072
DO - 10.1029/2022JB025072
M3 - Article
AN - SCOPUS:85147147513
SN - 2169-9313
VL - 128
JO - Journal of Geophysical Research: Solid Earth
JF - Journal of Geophysical Research: Solid Earth
IS - 1
M1 - e2022JB025072
ER -