Chemical and Physical Characteristics of Pulverized Tejon Lookout Granite Adjacent to the San Andreas and Garlock Faults: Implications for Earthquake Physics

Rockwell, T.; Sisk, M.; Girty, Gary H.; Dor, O.; Wechsler, Neta; Ben‐Zion, Yehuda

doi:10.1007/s00024-009-0514-1

Cited by 80 publications

(85 citation statements)

References 31 publications

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“…As pointed already, microstructures in the NOJ220 sample are very similar to the experimentally or naturally fragmented samples described by Aben et al (2016) and Dor et al (2006Dor et al ( , 2009 and Rockwell et al (2009) high confining pressure prevents complete pulverization but not fragmentation (Yuan et al, 2011). The confining pressure being in the 100 -300 MPa range when microstructures formed in the NOJ220 sample, the strain-rate threshold was probably not attained and the granodiorite was microfractured, but not pulverized.…”

Section: Implications For the Development Of The Damage Zonesupporting

confidence: 80%

“…The quartz grain described in the Figure 7 and displaying fractures radiating in a Hertzian pattern may also be compared to quartz grains in damaged sandstones along the San Andreas Fault (Dor et al, 2009). By 25 analogy, the opening of type 2 laumontite veins is tentatively attributed to a co-seismic or dynamic stage (Figure 14) although their orientation is more difficult to interpret (E-W sriking veins versus N50° striking Nojima fault).…”

Section: Laumontite-filled Veinsmentioning

confidence: 99%

“…Earthquakes characterizing the first period of seismic activity along the Nojima fault were M6 to M7 magnitude events 20 (Boullier et al, 2001) and their consequences may be compared to those of californian earthquakes along the San Andreas fault system where pulverized rocks were produced on the near surface within a 100 m wide zone (Dor et al, 2006 ;Rockwell et al, 2009). We believe that microstructures in the NOJ220 sample are representative of the incipient dynamic damage at depth induced by the propagation of a seismic rupture on the Nojima fault plane 51 m away from the studied sample.…”

Section: Implications For the Development Of The Damage Zonementioning

confidence: 99%

“…Outside the fault core, 1 to 10 3 m wide zones may be damaged by brittle failure of the surrounding rocks. Recently, several examples of pulverized rocks lacking significant shear have been described at the surface or subsurface within 100 to 200 m wide bands close to large faults such as the San Andreas fault (Dor et al, 2006 ;Rockwell et al, 2009;Wechsler et al, 2011) or the Arima-Takatsuki Line in Japan (Mitchell et al, 2011), and have been attributed to dynamic co-seismic damage. At the same time, high strain-rate 25 experiments on granite using Hopkinson bars without confinement have reproduced similar pulverized rocks (Xia et al, 2008) and predicted a dynamic shear stress threshold for pulverization (Doan and Gary, 2009).…”

Section: Introductionmentioning

confidence: 99%

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High stresses stored in fault zones: example of the Nojima fault (Japan)

Boullier¹,

Robach²,

Ildefonse³

et al. 2017

Preprint

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Abstract. During the last decade pulverized rocks have been described on outcrops along large active faults and attributed to damage related to a propagating seismic rupture front. Questions remain on the maximal lateral distance from the fault plane and maximal depth for dynamic damage to be imprinted in rocks. In order to document these questions, a core sample of granodiorite located at 51.3 m from the Nojima fault (Japan) that was drilled after the Hyogo-ken Nanbu (Kobe) earthquake is studied by using Electron Back-Scattered Diffraction (EBSD) and high resolution X-ray Laue 15 microdiffraction. Although located outside of the Nojima damage fault zone and macroscopically undeformed, the sample shows pervasive microfractures and local fragmentation that are attributed to the first stage of seismic activity along the Nojima fault characterized by laumontite as the main sealing mineral. EBSD mapping was used in order to characterize the crystallographic orientation and deformation microstructures in the sample, and X-ray microdiffraction to measure elastic strain and residual stresses in a quartz grain. Both methods give consistent results on the crystallographic orientation and 20show small and short wave-length misorientations associated with laumontite-sealed microfractures and alignments of tiny fluid inclusions. Deformation microstructures in quartz are symptomatic of the semi-brittle faulting regime, in which low temperature brittle, plastic deformation and stress-driven dissolution-deposition processes occur conjointly.Residual stresses are calculated from elastic strain measured by X-ray Laue microdiffraction and stress peaks at 100 MPa (mean 141 MPa). Such stress values are comparable to the peak strength of a damaged granodiorite from the damage zone 25 of the Nojima fault indicating that, although apparently macroscopically undeformed, the sample is actually highly damaged. The homogeneously distributed microfracturing of quartz is the microscopically visible imprint of this damage and suggests that high stresses were stored in the whole sample and not only concentrated on some crystal defects. It is proposed that the high residual stresses are the sum of the stress fields associated with individual dislocations, dislocation microstructures and originated from the dynamic damage related to the propagation of rupture fronts or seismic waves 30 associated to M6 to M7 earthquakes during Paleocene on the Nojima fault at a 3.7 -11.1 km depth (laumontite stability domain) where confining pressure prevented pulverization. The high residual stresses and the deformation microstructures Solid Earth Discuss., https://doi

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Section: Implications For the Development Of The Damage Zonesupporting

confidence: 80%

Section: Laumontite-filled Veinsmentioning

confidence: 99%

Section: Implications For the Development Of The Damage Zonementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

High stresses stored in fault zones: example of the Nojima fault (Japan)

Boullier¹,

Robach²,

Ildefonse³

et al. 2017

Preprint

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“…creation of new fracture surfaces; KOST-ROV and DAS, 1988;SCHOLZ, 2002;BEN-ZION, 2003). Field and microstructural observations suggest that heat production (frictional heat) dominates fracture surface energy at a point on a fault (CHESTER et al, 2005;PITTARELLO et al, 2008;ROCKWELL et al, 2009), although simulations of dynamic rupture suggest that off-fault deformation in the shallow crust may be of significant importance in the energy budget (BEN-ZION and SHI, 2005). Given that thermal diffusivity in most crustal rocks is low, and the duration of an individual slip pulse is typically a few seconds or less, most of the heat produced is restricted to a narrow band within and adjacent to the slip zone (SIBSON, 2003;RICE, 2006).…”

Section: Introductionmentioning

confidence: 99%

Principal Slip Zones in Limestone: Microstructural Characterization and Implications for the Seismic Cycle (Tre Monti Fault, Central Apennines, Italy)

Smith

Billi

Toro

et al. 2011

Pure Appl. Geophys.

123

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Earthquakes in central Italy, and in other areas worldwide, often nucleate within and rupture through carbonates in the upper crust. During individual earthquake ruptures, most fault displacement is thought to be accommodated by thin principal slip zones. This study presents detailed microstructural observations of the slip zones of the seismically active Tre Monti normal fault zone. All of the slip zones cut limestone, and geological constraints indicate exhumation from\2 km depth, where ambient temperatures are 100C. Scanning electron microscope observations suggest that the slip zones are composed of 100% calcite. The slip zones of secondary faults in the damage zone contain protocataclastic and cataclastic fabrics that are cross-cut by systematic fracture networks and stylolite dissolution surfaces. The slip zone of the principal fault has much more microstructural complexity, and contains a 2–10 mm thick ultracataclasite that lies immediately beneath the principal slip surface. The ultracataclasite itself is internally zoned; 200–300 lm-thick ultracataclastic sub-layers record extreme localization of slip. Syn-tectonic calcite vein networks spatially associated with the sub-layers suggest fluid involvement in faulting. The ultracataclastic sub-layers preserve compelling microstructural evidence of fluidization, and also contain peculiar rounded grains consisting of a central (often angular) clast wrapped by a laminated outer cortex of ultra-fine-grained calcite. These ‘‘clast-cortex grains’’ closely resemble those produced during layer fluidization in other settings, including the basal detachments of catastrophic landslides and saturated high-velocity friction experiments on clay-bearing gouges. An overprinting foliation is present in the slip zone of the principal fault, and electron backscatter diffraction analyses indicate the presence of a weak calcite crystallographic preferred orientation (CPO) in the fine-grained matrix. The calcite c-axes are systematically inclined in the direction of shear. We suggest that fluidization of ultracataclastic sub-layers and formation of clast-cortex grains within the principal slip zone occurred at high strain rates during propagation of seismic ruptures whereas development of an overprinting CPO occurred by intergranular pressure solution during post-seismic creep. Further work is required to document the range of microstructures in localized slip zones that cross-cut different lithologies, and to compare natural slip zone microstructures with those produced in controlled deformation experiments

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Fractal particle size distribution of pulverized fault rocks as a function of distance from the fault core

Muto

Nakatani

Nishikawa

et al. 2015

Geophysical Research Letters

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The size distributions of particle in pulverized rocks from the San Andreas fault and the Arima‐Takatsuki Tectonic Line were measured. The rocks are characterized by the development of opening mode fractures with an apparent lack of shear. Fragments in the rocks in both fault zones show a fractal size distribution down to the micron scale. Fractal dimensions, dependent on mineral type, decrease from 2.92 to 1.97 with increasing distance normal to the fault core. The fractal dimensions of the rocks are higher than those of both natural and experimentally created fault gouges measured in previous studies. Moreover, the dimensions are higher than the theoretically estimated upper fractal limit under confined comminution. Dimensions close to 3.0 have been reported in impact loading experiments. The observed characteristics indicate that pulverization is likely to have occurred by a dynamic stress pulse with instantaneous volumetric expansion, possibly during seismic rupture propagation similar to impact loading.

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Chemical and Physical Characteristics of Pulverized Tejon Lookout Granite Adjacent to the San Andreas and Garlock Faults: Implications for Earthquake Physics

Cited by 80 publications

References 31 publications

High stresses stored in fault zones: example of the Nojima fault (Japan)

High stresses stored in fault zones: example of the Nojima fault (Japan)

Principal Slip Zones in Limestone: Microstructural Characterization and Implications for the Seismic Cycle (Tre Monti Fault, Central Apennines, Italy)

Fractal particle size distribution of pulverized fault rocks as a function of distance from the fault core

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