Your search keyword '"SAFOD"' showing total 64 results

1. Characterization of the San Andreas Fault by Fault-Zone Trapped Waves at Seismic Experiment Site, Parkfield, California: A Review

Author

Li, Yong-Gang, Li, Yong-Gang, editor, Zhang, Yongxian, editor, and Wu, Zhongliang, editor

Published

2022

2. Faulting processes in active faults – Evidences from TCDP and SAFOD drill core samples

Author

Janssen, C, Wirth, R, Wenk, H-R, Morales, L, Naumann, R, Kienast, M, Song, S-R, and Dresen, G

Subjects

SAFOD, TCDP, Microstructures, Fault rock composition, CPO, EBSD, Geology, Geochemistry & Geophysics

Abstract

The microstructures, mineralogy and chemistry of representative samples collected from the cores of the San Andreas Fault drill hole (SAFOD) and the Taiwan Chelungpu-Fault Drilling project (TCDP) have been studied using optical microscopy, TEM, SEM, XRD and XRF analyses. SAFOD samples provide a transect across undeformed host rock, the fault damage zone and currently active deforming zones of the San Andreas Fault. TCDP samples are retrieved from the principal slip zone (PSZ) and from the surrounding damage zone of the Chelungpu Fault. Substantial differences exist in the clay mineralogy of SAFOD and TCDP fault gouge samples. Amorphous material has been observed in SAFOD as well as TCDP samples. In line with previous publications, we propose that melt, observed in TCDP black gouge samples, was produced by seismic slip (melt origin) whereas amorphous material in SAFOD samples was formed by comminution of grains (crush origin) rather than by melting. Dauphiné twins in quartz grains of SAFOD and TCDP samples may indicate high seismic stress. The differences in the crystallographic preferred orientation of calcite between SAFOD and TCDP samples are significant. Microstructures resulting from dissolution-precipitation processes were observed in both faults but are more frequently found in SAFOD samples than in TCDP fault rocks. As already described for many other fault zones clay-gouge fabrics are quite weak in SAFOD and TCDP samples. Clay-clast aggregates (CCAs), proposed to indicate frictional heating and thermal pressurization, occur in material taken from the PSZ of the Chelungpu Fault, as well as within and outside of the SAFOD deforming zones, indicating that these microstructures were formed over a wide range of slip rates. © 2014 Elsevier Ltd.

Published

2014

3. Seismic Velocity Estimation Using Passive Downhole Distributed Acoustic Sensing Records: Examples From the San Andreas Fault Observatory at Depth.

Author

Lellouch, A., Yuan, S., Spica, Z., Biondi, B., and Ellsworth, W. L.

Subjects

*SEISMIC wave velocity, *SEISMIC event location, *ACOUSTIC imaging, *GEOPHONE

Abstract

Structural imaging and event location require an accurate estimation of the seismic velocity. However, active seismic surveys used to estimate it are expensive and time‐consuming. During the last decade, fiber‐optic‐based distributed acoustic sensing has emerged as a reliable, enduring, and high‐resolution seismic sensing technology. We show how downhole distributed acoustic sensing passive records from the San Andreas Fault Observatory at Depth can be used for seismic velocity estimation. Using data recorded from earthquakes propagating near‐vertically, we compute seismic velocities using first‐break picking as well as slant stack decomposition. This methodology allows for the estimation of both P and S wave velocity models. We also use records of the ambient seismic field for interferometry and P wave velocity model extraction. Results are compared to a regional model obtained from surface seismic as well as a conventional downhole geophone survey. We find that using recorded earthquakes, we obtain the highest P wave model resolution. In addition, it is the only method that allows for S wave velocity estimation. Computed P and S models unravel three distinct areas at the depth range of 50‐750 m, which were not present in the regional model. In addition, we find high VP/VS values near the surface and a possible VP/VS anomaly about 500 m deep. We confirm its existence by observing a strong S‐P mode conversion at that depth. Key Points: A seismically active area is recorded using distributed acoustic sensing of a downhole fiberWe estimate P‐ and S‐ wave velocities using fiber data and compare them with conventional surveysVelocity analysis unveils a geological structure at the San Andreas Fault Observatory at Depth location [ABSTRACT FROM AUTHOR]

Published

2019

4. A study of secondary pyrite deformation and calcite veins in SAFOD damage zone with implications for aseismic creep deformation mechanism at depths >3 km.

Author

Hadizadeh, Jafar and Boyle, Alan P.

Subjects

*PYRITES, *DEFORMATIONS (Mechanics), *CALCITE, *MICROSTRUCTURE, *ROCK creep

Abstract

Abstract Previous studies of the San Andreas Fault damage-zone samples from the San Andreas Fault Observatory at Depth (SAFOD) have identified a variety of tectonic microstructures including pressure solution cleavage, calcite-sealed fractures vein fabric, and pyrite and anhydrite hydrothermal fracture sealing. Understanding the deformation provenance of the damage zone rocks and operative deformation mechanism(s) based on preserved microstructures provide insight into overall deformation behavior of the entire seismogenic zone in the creeping section of this transform fault. We analysed the deformation of hydrothermal secondary pyrite in connection with network of calcite veins in a sample of foliated ultracataclasites bordering the actively creeping Southwestern Deforming Zone (SDZ), using SEM, EBSD and CL microscopy. The results show that calcite veins associated with the pressure solution cleavage are crosscut by the secondary pyrite deformed under a range of P-T conditions. Relatively undeformed secondary pyrite is found sealing implosion microbreccia. Our review of previously available data indicates that the damage zone rocks may represent a collage of structural and compositional domains from both locked and creeping sections of the SAF. This interpretation together with results of this study suggest that weak-clay frictional deformation mechanism(s) is likely to be the predominant aseismic creep mechanism at depths below the SAFOD. Highlights • We sought to constrain aseismic creep deformation mechanisms operative at depths below the SAFOD. • EBSD and CL methods were used to obtain deformation-related P-T conditions in a SAFOD core sample. • Calcite veins and secondary pyrite were linked to deformation, the fault uplift, and displacement. • Frictional deformation of weak clays and creep by pressure solution were considered. • The mechanisms associated with weak clays are likely to predominate aseismic creep at depths>3 km. [ABSTRACT FROM AUTHOR]

Published

2018

5. Serpentinite‐Rich Gouge in a Creeping Segment of the Bartlett Springs Fault, Northern California: Comparison With SAFOD and Implications for Seismic Hazard.

Author

Moore, Diane E., McLaughlin, Robert J., and Lienkaemper, James J.

Abstract

An exposure of a creeping segment of the Bartlett Springs Fault (BSF), part of the San Andreas Fault system in northern California, is a ~1.5‐m‐wide zone of serpentinite‐bearing fault gouge cutting through Late Pleistocene fluvial deposits. The fault gouge consists of porphyroclasts of antigorite serpentinite, talc, chlorite, and tremolite‐actinolite, along with some Franciscan metamorphic rocks, in a matrix of the same materials. The Mg‐mineral assemblage is stable at temperatures above 250–300 °C. The BSF gouge is interpreted to have been tectonically incorporated into the fault from depths near the base of the seismogenic zone and to have risen buoyantly to the surface where it is now undergoing right‐lateral displacement. The ultramafic‐rich composition, frictional properties, and inferred mode of emplacement of the BSF serpentinitic gouge correspond to those of the creeping traces of the San Andreas Fault identified in the SAFOD (San Andreas Fault Observatory at Depth) drill hole. This suggests a common origin for creep at both locations. A tectonic model for the source of the ultramafic‐rich materials in the BSF is proposed that potentially could explain the distribution of creep throughout the northernmost San Andreas Fault system. Key Points: A creeping segment of the Bartlett Springs Fault consists of antigorite serpentinite‐rich gouge tectonically entrained from >9 km depthThe gouge is a higher‐grade, greenschist‐facies equivalent of that found in core from the creeping central San Andreas FaultA proposed tectonic model for the ultramafic source can explain the distribution of creep in the northern San Andreas Fault system [ABSTRACT FROM AUTHOR]

Published

2018

6. Grain size-dependent strength of phyllosilicate-rich gouges in the shallow crust: Insights from the SAFOD site.

Author

Phillips, Noah John and White, Joseph Clancy

Abstract

The San Andreas Fault Observatory at Depth (SAFOD) drilling project directly sampled a transitional (between creeping and locked) segment of the San Andreas Fault at 2.7 km depth. At the site, changes in strain rate occur between periods of coseismic slip (>10−7 s−1) and interseismic creep (10−10 s−1) over decadal scales (~30 years). Microstructural observations of core retrieved from the SAFOD site show throughgoing fractures and gouge-rich cores within the fractures, evidence of predominantly brittle deformation mechanisms. Within the gouge-rich cores, strong phases show evidence of deformation by pressure solution once the grain size is reduced to a critical effective grain size. Models of pressure solution-accommodated creep for quartz-phyllosilicate mixtures indicate that viscous weakening of quartz occurs during the interseismic period once a critical effective grain size of 1 μm is achieved, consistent with microstructural observations. This causes pronounced weakening, as the strength of the mixture is then controlled by the frictional properties of the phyllosilicate phases. These results have pronounced implications for the internal deformation of fault zones in the shallow crust, where at low strain rates, deformation is accommodated by both viscous and brittle deformation mechanisms. As strain rates increase, the critical effective grain size for weakening decreases, localizing deformation into the finest-grained gouges until deformation can no longer be accommodated by viscous processes and purely brittle failure occurs. [ABSTRACT FROM AUTHOR]

Published

2017

7. Scientific Drilling Into the San Andreas Fault Zone —An Overview of SAFOD’s First Five Years

Author

Stephen Hickman, Mark Zoback, and William Ellsw

Subjects

SAFOD, Geology, QE1-996.5

Abstract

The San Andreas Fault Observatory at Depth (SAFOD)was drilled to study the physical and chemical processes controlling faulting and earthquake generation along an active, plate-bounding fault at depth. SAFOD is located near Parkfield, California and penetrates a section of the fault that is moving due to a combination of repeating microearthquakes and fault creep. Geophysical logs define the SanAndreas Fault Zone to be relatively broad (~200 m), containing several discrete zones only 2–3 m wide that exhibit very low P- and S-wave velocities and low resistivity. Two of these zones have progressively deformed the cemented casing at measured depths of 3192 m and 3302 m. Cores from both deforming zones contain a pervasively sheared, cohesionless, foliated fault gouge that coincides with casing deformation and explains the observed extremely low seismic velocities and resistivity. These cores are being now extensivelytested in laboratories around the world, and their composition, deformation mechanisms, physical properties, and rheological behavior are studied. Downhole measurements show that within 200 m (maximum) of the active fault trace, the direction of maximum horizontal stress remains at a high angle to the San Andreas Fault, consistent with other measurements. The results from the SAFOD Main Hole, together with the stress state determined in the Pilot Hole, are consistent with a strong crust/weak fault model of the San Andreas. Seismic instrumentation has been deployed to study physics of faulting—earthquake nucleation, propagation, and arrest—in order to test how laboratory-derived concepts scale up to earthquakes occurring in nature.

Published

2011

8. Low-Velocity Damage Zone on the San Andreas Fault at Depth near SAFOD Site at Parkfield Delineated by Fault- Zone Trapped Waves

Author

John E. Vidale, Peter E. Malin, and Yong-Gang Li

Subjects

SAFOD, Geology, QE1-996.5

Published

2007

9. Monitoring of Rock Mass Behavior at the Closest Proximity to Hypocenters in South African Gold Mines

Author

The Research Group for Semi-controlled Earthquake- Generation Experiments in South African Deep Gold Mines and Hiroshi Ogasawara

Subjects

SAFOD, Geology, QE1-996.5

Published

2007

10. Structure and Properties of the San Andreas Fault in Central California: Recent Results from the SAFOD Experiment

Author

Clifford Thurber, Steven Roecker, Naomi Boness, Peter Malin, Mark Zoback, William Ellsworth, and Stephen Hickman

Subjects

SAFOD, Geology, QE1-996.5

Published

2007

11. San Andreas Fault Zone Mineralogy, Geochemistry, and Physical Properties from SAFOD Cuttings and Core

Author

Diane E. Moore, Anja M. Schleicher, Ben A. van der, Frederick M. Chester, Judith S. Chester, David L. Kirschner, D.C. Barton, Sarah D. Draper, Jim P. Evans, Sheryl Tembe, David. A. Lockner, Stephen Hickman, John G. Solum, Carolyn Morrow, Kelly Bradbury, Wendy M. Calvin, and Teng-fong Wong

Subjects

SAFOD, Geology, QE1-996.5

Published

2007

12. Seismology inside the Fault Zone: Applications to Fault-Zone Properties and Rupture Dynamics

Author

Felix Waldhauser, Volker Oye, Clifford H. Thurber, Robert Nadeau, Steven W. Roecker, Kazutoshi Imanishi, Peter E. Malin, William L. Ellsworth, Namoi L. Boness, Stephen H. Hickman, and Mark D. Zoback

Subjects

SAFOD, Geology, QE1-996.5

Published

2007

13. Constraints on paleofluid sources using the clumped-isotope thermometry of carbonate veins from the SAFOD (San Andreas Fault Observatory at Depth) borehole.

Author

Luetkemeyer, P. Benjamin, Kirschner, David L., Huntington, Katharine W., Chester, Judith S., Chester, Frederick M., and Evans, James P.

Subjects

*FAULT zones, *THERMOMETRY, *STRUCTURAL geology, *DRILLING & boring, *DEFORMATIONS (Mechanics), *PLATE tectonics

Abstract

The San Andreas Fault Observatory at Depth (SAFOD), near Parkfield, California, is a borehole drilled through two active deforming zones of the San Andreas fault, the Southwest Deforming Zone (SDZ) and the Central Deforming Zone (CDZ). These zones accommodate displacement by seismic slip and aseismic creep. Elevated fluid pressures and fluid–rock interactions have been proposed to explain the low apparent strength and aseismic creep observed, but the origin of the fluids and existence of high fluid pressures remains uncertain. We use clumped-isotope thermometry and δ 18 O–δ 13 C compositions of calcite in veins to constrain the origin of paleofluids and compare these results to the isotopic composition of modern-day pore fluids from the SAFOD borehole and nearby areas. We observe that: (1) calcite vein temperatures vary from 81 to 134 °C, which overlaps the current ambient borehole temperatures of 110–115 °C at sampled depths; (2) vein calcite is not in carbon isotope equilibrium with modern-day pore fluids; (3) the δ 18 O values of paleofluids close to the SDZ and CDZ, calculated from vein δ 18 O and temperature data, are not in equilibrium with local modern-day pore waters but approach equilibrium with modern pore waters far from these zones; and (4) syntectonic vein calcite is only in C- and O-isotopic equilibrium with their host rocks within the SDZ and CDZ. Spatial patterns of δ 18 O and δ 13 C show little evidence for across-fault fluid-flow. Clumped isotope temperatures are consistent with locally-derived fluid sources, but not with continuous or episodic replenishment of fluids from shallow sedimentary brines or deep fluid sources. Our findings are compatible with flow of meteoric fluids from the southwestern damage zone into the SDZ and CDZ, which would have favored the formation of weak phyllosilicates and contributed to the present day weakness of the two actively deforming zones. [ABSTRACT FROM AUTHOR]

Published

2016

14. Elevated time-dependent strengthening rates observed in San Andreas Fault drilling samples.

Author

Ikari, Matt J., Carpenter, Brett M., Vogt, Christoph, and Kopf, Achim J.

Subjects

*EARTHQUAKES, *SEISMOLOGY, *DRILLING & boring, *SHEARING force, *POWER law (Mathematics)

Abstract

The central San Andreas Fault in California is known as a creeping fault, however recent studies have shown that it may be accumulating a slip deficit and thus its seismogenic potential should be seriously considered. We conducted laboratory friction experiments measuring time-dependent frictional strengthening (healing) on fault zone and wall rock samples recovered during drilling at the San Andreas Fault Observatory at Depth (SAFOD), located near the southern edge of the creeping section and in the direct vicinity of three repeating microearthquake clusters. We find that for hold times of up to 3000 s, frictional healing follows a log-linear dependence on hold time and that the healing rate is very low for a sample of the actively shearing fault core, consistent with previous results. However, considering longer hold times up to ∼350,000 s, the healing rate accelerates such that the data for all samples are better described by a power law relation. In general, samples having a higher content of phyllosilicate minerals exhibit low log-linear healing rates, and the notably clay-rich fault zone sample also exhibits strong power-law healing when longer hold times are included. Our data suggest that weak faults, such as the creeping section of the San Andreas Fault, can accumulate interseismic shear stress more rapidly than expected from previous friction data. Using the power-law dependence of frictional healing on hold time, calculations of recurrence interval and stress drop based on our data accurately match observations of discrete creep events and repeating M w = 2 earthquakes on the San Andreas Fault. [ABSTRACT FROM AUTHOR]

Published

2016

15. Hydrothermal frictional strengths of rock and mineral samples relevant to the creeping section of the San Andreas Fault.

Author

Moore, Diane E., Lockner, David A., and Hickman, Stephen

Subjects

*HYDROTHERMAL deposits, *SEISMOLOGY, *SAPONITE, *FRICTION, *CHLORITE minerals

Abstract

We compare frictional strengths in the temperature range 25–250 °C of fault gouge from SAFOD (CDZ and SDZ) with quartzofeldspathic wall rocks typical of the central creeping section of the San Andreas Fault (Great Valley sequence and Franciscan Complex). The Great Valley and Franciscan samples have coefficients of friction, μ > 0.35 at all experimental conditions. Strength is unchanged between 25° and 150 °C, but μ increases at higher temperatures, exceeding 0.50 at 250 °C. Both samples are velocity strengthening at room temperature but show velocity-weakening behavior beginning at 150 °C and stick-slip motion at 250 °C. These rocks, therefore, have the potential for unstable seismic slip at depth. The CDZ gouge, with a high saponite content, is weak (μ = 0.09–0.17) and velocity strengthening in all experiments, and μ decreases at temperatures above 150 °C. Behavior of the SDZ is intermediate between the CDZ and wall rocks: μ < 0.2 and does not vary with temperature. Although saponite is probably not stable at depths greater than ∼3 km, substitution of the frictionally similar minerals talc and Mg-rich chlorite for saponite at higher temperatures could potentially extend the range of low strength and stable slip down to the base of the seismogenic zone. [ABSTRACT FROM AUTHOR]

Published

2016

16. SAFOD Phase III Core Sampling and Data Management at the Gulf Coast Repository

Author

David Lockner, Judith S. Chester, Frederick M. Chester, Phil Rumford, John Firth, and Bradley Weymer

Subjects

SAFOD, Geology, QE1-996.5

Abstract

The San Andreas Fault Observatory at Depth (SAFOD)project is yielding new insight into the San Andreas Fault (Zoback et al., 2010; Zoback et al., this issue). SAFOD drilling started in 2002 with a pilot hole, and proceeded with three phrases of drilling and coring during the summers of 2004, 2005, and 2007 (Fig. 1). One key component of theproject is curation, sampling, and documentation of SAFOD core usage at the Integrated Ocean Drilling Program’s (IODP) Gulf Coast Repository (GCR) at Texas A&M University. We present here the milestones accomplished over the past two years of sampling Phase III core at the GCR.

Published

2011

17. Electron Microscopy of Clay Minerals in Mudrocks from the San Andreas Fault Observatory at Depth (SAFOD)

Author

Laurence N. Warr, Ben A. van der Pluijm, Anja M. Schleicher, and John G. Solum

Subjects

SAFOD, Geology, QE1-996.5

Published

2007

18. New Developments in Long-Term Downhole Monitoring Arrays

Author

Jochem Kück and Bernhard Prevedel

Subjects

SAFOD, Geology, QE1-996.5

Abstract

The long-term observation of active geological processes is a major research goal in an increasing number of scientific drilling projects. An extended monitoring phase within a potentially hostile environment (e.g., temperature, pressure, salinity) requires new long-lasting and robust instrumentation currently unavailable from either industry or academia. Extended exposure of instrument packages to extreme conditions will typically cause seals to weaken and fail,electronic parts to break under permanent load, and sensors to degrade or develop strong drift. In the framework of scientific exploration, there are currently several major research projects targeting fault zone drilling and in situ measurements to monitor physical and chemical conditions before, during, and after seismic events. Planning has now begun for tool development, testing, and continuous long-term monitoring for the San Andreas Fault Zone Observatory at Depth, SAFOD (Parkfi eld, Calif., U.S.A.; See article on page 32.).

Published

2006

19. A “slice-and-view” (FIB–SEM) study of clay gouge from the SAFOD creeping section of the San Andreas Fault at ∼2.7 km depth.

Author

Warr, Laurence N., Wojatschke, Jasmaria, Carpenter, Brett M., Marone, Chris, Schleicher, Anja M., and van der Pluijm, Ben A.

Subjects

*FAULT gouge, *EARTHQUAKES, *CREEP (Materials), *EARTHQUAKE resistant design, *CLAY

Abstract

The San Andreas Fault is one of the most studied earthquake-generating structures on Earth, but the reason that some sections are anomalously weak, and creep without apparent seismicity, remains poorly understood. Here, we present results from nanoscale (FIB–SEM) 3D microstructural observations of weak (friction coefficient of 0.095) SAFOD clay fault gouge containing serpentinite clasts, recovered from the active Central Deforming Zone at ∼2.7 km vertical depth. Our nanoscale observations confirm that frictional slip and extreme weakness occur via deformation of smectite clay that forms a shear fabric within the fault zone. We infer that creep initiates by fracture-controlled, substrate growth of oriented Mg-smectite on R, P and Y shears, followed by clay smearing and ductile flow of an evolving and expanding clay matrix. At the crystal-scale, pervasive sliding occurs along hydrated smectite interlayers and surfaces occupied by exchangeable Mg- and Ca-ions, with slip typically spaced at 3–5 lattice layers apart. We conclude that the strength and seismic behaviour of major tectonic faults at shallow crustal levels evolves as clay fabric develops with accumulated fault slip. [ABSTRACT FROM AUTHOR]

Published

2014

20. Comparative mineral chemistry and textures of SAFOD fault gouge and damage-zone rocks.

Author

Moore, Diane E.

Subjects

*GEOCHEMISTRY, *FAULT gouge, *ROCK deformation, *SERPENTINITE, *STRAINS & stresses (Mechanics)

Abstract

Creep in the San Andreas Fault Observatory at Depth (SAFOD) drillhole is localized to two foliated gouges, the central deforming zone (CDZ) and southwest deforming zone (SDZ). The gouges consist of porphyroclasts of serpentinite and sedimentary rock dispersed in a foliated matrix of Mg-smectite clays that formed as a result of shearing-enhanced reactions between the serpentinite and quartzofeldspathic rocks. The CDZ takes up most of the creep and exhibits differences in mineralogy and texture from the SDZ that are attributable to its higher shearing rate. In addition, a ∼0.2-m-wide sector of the CDZ at its northeastern margin (NE-CDZ) is identical to the SDZ and may represent a gradient in creep rate across the CDZ. The SDZ and NE-CDZ have lower clay contents and larger porphyroclasts than most of the CDZ, and they contain veinlets and strain fringes of calcite in the gouge matrix not seen elsewhere in the CDZ. Matrix clays in the SDZ and NE-CDZ are saponite and corrensite, whereas the rest of the CDZ lacks corrensite. Saponite is younger than corrensite, reflecting clay crystallization under declining temperatures, and clays in the more actively deforming portions of the CDZ have better equilibrated to the lower-temperature conditions. [ABSTRACT FROM AUTHOR]

Published

2014

21. Faulting processes in active faults – Evidences from TCDP and SAFOD drill core samples.

Author

Janssen, C., Wirth, R., Wenk, H.-R., Morales, L., Naumann, R., Kienast, M., Song, S.-R., and Dresen, G.

Subjects

*GEOLOGIC faults, *DRILLING & boring, *TRANSECT method, *FRACTURE mechanics, *MICROSTRUCTURE, *DISSOLUTION (Chemistry)

Abstract

Abstract: The microstructures, mineralogy and chemistry of representative samples collected from the cores of the San Andreas Fault drill hole (SAFOD) and the Taiwan Chelungpu-Fault Drilling project (TCDP) have been studied using optical microscopy, TEM, SEM, XRD and XRF analyses. SAFOD samples provide a transect across undeformed host rock, the fault damage zone and currently active deforming zones of the San Andreas Fault. TCDP samples are retrieved from the principal slip zone (PSZ) and from the surrounding damage zone of the Chelungpu Fault. Substantial differences exist in the clay mineralogy of SAFOD and TCDP fault gouge samples. Amorphous material has been observed in SAFOD as well as TCDP samples. In line with previous publications, we propose that melt, observed in TCDP black gouge samples, was produced by seismic slip (melt origin) whereas amorphous material in SAFOD samples was formed by comminution of grains (crush origin) rather than by melting. Dauphiné twins in quartz grains of SAFOD and TCDP samples may indicate high seismic stress. The differences in the crystallographic preferred orientation of calcite between SAFOD and TCDP samples are significant. Microstructures resulting from dissolution–precipitation processes were observed in both faults but are more frequently found in SAFOD samples than in TCDP fault rocks. As already described for many other fault zones clay-gouge fabrics are quite weak in SAFOD and TCDP samples. Clay-clast aggregates (CCAs), proposed to indicate frictional heating and thermal pressurization, occur in material taken from the PSZ of the Chelungpu Fault, as well as within and outside of the SAFOD deforming zones, indicating that these microstructures were formed over a wide range of slip rates. [Copyright &y& Elsevier]

Published

2014

22. Deep permeability of the San Andreas Fault from San Andreas Fault Observatory at Depth (SAFOD) core samples.

Author

Morrow, C.A., Lockner, D.A., Moore, D.E., and Hickman, S.

Subjects

*PERMEABILITY, *SHEAR zones, *SURFACE defects, *STRUCTURAL geology

Abstract

Abstract: The San Andreas Fault Observatory at Depth (SAFOD) scientific borehole near Parkfield, California crosses two actively creeping shear zones at a depth of 2.7 km. Core samples retrieved from these active strands consist of a foliated, Mg-clay-rich gouge containing porphyroclasts of serpentinite and sedimentary rock. The adjacent damage zone and country rocks are comprised of variably deformed, fine-grained sandstones, siltstones, and mudstones. We conducted laboratory tests to measure the permeability of representative samples from each structural unit at effective confining pressures, P e up to the maximum estimated in situ P e of 120 MPa. Permeability values of intact samples adjacent to the creeping strands ranged from 10−18 to 10−21 m2 at P e = 10 MPa and decreased with applied confining pressure to 10−20–10−22 m2 at 120 MPa. Values for intact foliated gouge samples (10−21–6 × 10−23 m2 over the same pressure range) were distinctly lower than those for the surrounding rocks due to their fine-grained, clay-rich character. Permeability of both intact and crushed-and-sieved foliated gouge measured during shearing at P e ≥ 70 MPa ranged from 2 to 4 × 10−22 m2 in the direction perpendicular to shearing and was largely insensitive to shear displacement out to a maximum displacement of 10 mm. The weak, actively-deforming foliated gouge zones have ultra-low permeability, making the active strands of the San Andreas Fault effective barriers to cross-fault fluid flow. The low matrix permeability of the San Andreas Fault creeping zones and adjacent rock combined with observations of abundant fractures in the core over a range of scales suggests that fluid flow outside of the actively-deforming gouge zones is probably fracture dominated. [Copyright &y& Elsevier]

Published

2014

23. Clay fabrics in SAFOD core samples

Author

Janssen, C., Kanitpanyacharoen, W., Wenk, H.-R., Wirth, R., Morales, L., Rybacki, E., Kienast, M., and Dresen, G.

Subjects

*SCANNING electron microscopy techniques, *TRANSMISSION electron microscopy, *POROSITY, *CATACLASTIC rocks, *CLAY minerals, *GEOLOGIC faults, *PORE fluids

Abstract

Abstract: With optical microscopy, scanning electron microscopy (SEM), transmission electron microscopy (TEM), and synchrotron X-ray diffraction measurements, we analyzed clay microfabrics in ultracataclastic/gouge and cataclastic core samples obtained from the main bore hole of the San Andreas Fault observatory at depth (SAFOD). The analysis reveals a significant contrast between weak clay fabrics observed in the core samples with synchrotron X-ray fabric measurements and strong degree of preferred alignment for clay particles documented with the optical microscope. TEM and SEM observations also show distinct zones of locally aligned and randomly oriented clay minerals. The lack of a strong fabric may be attributed to randomly oriented matrix sheet silicates dominating the fault rocks. The presence of weak fabrics in intensely strained ultracataclasites/fault gouges is attributed to 1) newly formed clay minerals that grew in many orientations, 2) folded and kinked clay minerals, and 3) clay particles that are wrapped around grains. In addition, the locally aligned clay particles may act as barriers to fluid flow, which in turn decrease porosity, expel intergranular pore fluids, and consequently, may increase fluid pressure. [Copyright &y& Elsevier]

Published

2012

24. A microstructural study of fault rocks from the SAFOD: Implications for the deformation mechanisms and strength of the creeping segment of the San Andreas Fault

Author

Hadizadeh, Jafar, Mittempergher, Silvia, Gratier, Jean-Pierre, Renard, Francois, Di Toro, Giulio, Richard, Julie, and Babaie, Hassan A.

Subjects

*GEOLOGIC faults, *MICROSTRUCTURE, *ROCK deformation, *STRENGTH of materials, *ROCK creep, *STRUCTURAL geology, *SMECTITE

Abstract

Abstract: The San Andreas Fault zone in central California accommodates tectonic strain by stable slip and microseismic activity. We study microstructural controls of strength and deformation in the fault using core samples provided by the San Andreas Fault Observatory at Depth (SAFOD) including gouge corresponding to presently active shearing intervals in the main borehole. The methods of study include high-resolution optical and electron microscopy, X-ray fluorescence mapping, X-ray powder diffraction, energy dispersive X-ray spectroscopy, white light interferometry, and image processing. The fault zone at the SAFOD site consists of a strongly deformed and foliated core zone that includes 2–3 m thick active shear zones, surrounded by less deformed rocks. Results suggest deformation and foliation of the core zone outside the active shear zones by alternating cataclasis and pressure solution mechanisms. The active shear zones, considered zones of large-scale shear localization, appear to be associated with an abundance of weak phases including smectite clays, serpentinite alteration products, and amorphous material. We suggest that deformation along the active shear zones is by a granular-type flow mechanism that involves frictional sliding of microlithons along phyllosilicate-rich Riedel shear surfaces as well as stress-driven diffusive mass transfer. The microstructural data may be interpreted to suggest that deformation in the active shear zones is strongly displacement-weakening. The fault creeps because the velocity strengthening weak gouge in the active shear zones is being sheared without strong restrengthening mechanisms such as cementation or fracture sealing. Possible mechanisms for the observed microseismicity in the creeping segment of the SAF include local high fluid pressure build-ups, hard asperity development by fracture-and-seal cycles, and stress build-up due to slip zone undulations. [Copyright &y& Elsevier]

Published

2012

25. Dating deep? Luminescence studies of fault gouge from the San Andreas Fault zone 2.6 km beneath Earth's surface.

Author

Spencer, Joel Q.G., Hadizadeh, Jafar, Gratier, Jean-Pierre, and Doan, Mai-Linh

Subjects

THERMOLUMINESCENCE dating, FAULT gouge, MICROSTRUCTURE, RADIOACTIVE dating, MICROELECTROMECHANICAL systems, SEISMIC waves, SURFACE of the earth

Abstract

This study aims to assess whether luminescence emission from fault gouge samples from the San Andreas Fault Observatory at Depth (SAFOD) can be used to determine the age distribution of distinct deformation microstructures. Such age determination could help constrain some of the proposed micromechanical models for shear localization in fault gouge, in addition to providing more accurate time constraint on the seismic cycle itself. The mechanism by which previously trapped charge is reset in minerals in fault gouge is thought to be a combination of frictional heating and mechanical deformation, and these processes may be localized to grain surfaces. An added dating complexity specific to deep samples is the high ambient temperature conditions, which act as a barrier to charge storage in lower energy trapping sites. In this work luminescence experiments are being conducted on minerals from whole-rock samples of intact fault gouge from the SAFOD Phase III core. Initial studies indicate (i) the thermal and radiation history of the mineral lattice can be assessed with TL, (ii) trap resetting is evident in both TL and IRSL data, (iii) a small charge-trapping window between drill hole ambient temperature of ∼112 °C and higher energy lattice excitation via rupture events is evident in TL data from ∼300 to 400 °C, and we tentatively link the source of IRSL to TL within this 300–400 °C region, (iv) IRSL data have low natural intensity but good luminescence characteristics, and (v) SAR IRSL D e data have high over-dispersion but demonstrate ages ranging from decades to centuries may be measured. [ABSTRACT FROM AUTHOR]

Published

2012

26. Correlation of clayey gouge in a surface exposure of serpentinite in the San Andreas Fault with gouge from the San Andreas Fault Observatory at Depth (SAFOD)

Author

Moore, Diane E. and Rymer, Michael J.

Subjects

*SERPENTINITE, *MAGNESIUM, *SEDIMENTARY rocks, *OPHIOLITES, *PHYLLOSILICATES

Abstract

Abstract: Magnesium-rich clayey gouge similar to that comprising the two actively creeping strands of the San Andreas Fault in drill core from the San Andreas Fault Observatory at Depth (SAFOD) has been identified in a nearby outcrop of serpentinite within the fault zone at Nelson Creek. Each occurrence of the gouge consists of porphyroclasts of serpentinite and sedimentary rocks dispersed in a fine-grained, foliated matrix of Mg-rich smectitic clays. The clay minerals in all three gouges are interpreted to be the product of fluid-assisted, shear-enhanced reactions between quartzofeldspathic wall rocks and serpentinite that was tectonically entrained in the fault from a source in the Coast Range Ophiolite. We infer that the gouge at Nelson Creek connects to one or both of the gouge zones in the SAFOD core, and that similar gouge may occur at depths in between. The special significance of the outcrop is that it preserves the early stages of mineral reactions that are greatly advanced at depth, and it confirms the involvement of serpentinite and the Mg-rich phyllosilicate minerals that replace it in promoting creep along the central San Andreas Fault. [Copyright &y& Elsevier]

Published

2012

27. Lithology and internal structure of the San Andreas fault at depth based on characterization of Phase 3 whole-rock core in the San Andreas Fault Observatory at Depth (SAFOD) borehole

Author

Bradbury, Kelly K., Evans, James P., Chester, Judith S., Chester, Frederick M., and Kirschner, David L.

Subjects

*PETROLOGY, *BOREHOLE mining, *DRILLING & boring, *DEFORMATIONS (Mechanics), *SANDSTONE, *SEDIMENTARY rocks, *CREEP (Materials)

Abstract

Abstract: We characterize the lithology and structure of the spot core obtained in 2007 during Phase 3 drilling of the San Andreas Fault Observatory at Depth (SAFOD) in order to determine the composition, structure, and deformation processes of the fault zone at 3km depth where creep and microseismicity occur. A total of approximately 41m of spot core was taken from three separate sections of the borehole; the core samples consist of fractured arkosic sandstones and shale west of the SAF zone (Pacific Plate) and sheared fine-grained sedimentary rocks, ultrafine black fault-related rocks, and phyllosilicate-rich fault gouge within the fault zone (North American Plate). The fault zone at SAFOD consists of a broad zone of variably damaged rock containing localized zones of highly concentrated shear that often juxtapose distinct protoliths. Two zones of serpentinite-bearing clay gouge, each meters-thick, occur at the two locations of aseismic creep identified in the borehole on the basis of casing deformation. The gouge primarily is comprised of Mg-rich clays, serpentinite (lizardite±chrysotile) with notable increases in magnetite, and Ni-Cr-oxides/hydroxides relative to the surrounding host rock. The rocks surrounding the two creeping gouge zones display a range of deformation including fractured protolith, block-in-matrix, and foliated cataclasite structure. The blocks and clasts predominately consist of sandstone and siltstone embedded in a clay-rich matrix that displays a penetrative scaly fabric. Mineral alteration, veins and fracture-surface coatings are present throughout the core, and reflect a long history of syn-deformation, fluid-rock reaction that contributes to the low-strength and creep in the meters-thick gouge zones. [Copyright &y& Elsevier]

Published

2011

28. Low-temperature deformation in calcite veins of SAFOD core samples (San Andreas Fault) — Microstructural analysis and implications for fault rheology

Author

Rybacki, E., Janssen, C., Wirth, R., Chen, K., Wenk, H.-R., Stromeyer, D., and Dresen, G.

Subjects

*ROCK deformation, *CALCITE, *VEINS (Geology), *MICROSTRUCTURE, *RHEOLOGY, *PIEZOMETERS, *FAULT gouge, *SANDSTONE

Abstract

Abstract: The microstructures of four core samples from the San Andreas Fault Observatory at Depth (SAFOD) were investigated with optical and transmission electron microscopy. These samples, consisting of sandstone, siltstone, and fault gouge from phase III of the drilling campaign (3141–3307m MD), show a complex composition of quartz, feldspar, clays, and amorphous material. Microstructures indicate intense shearing and dissolution–precipitation as main deformation processes. The samples also contain abundant veins filled with calcite. Within the inspected veins the calcite grains exhibit different degrees of deformation with evidence for twinning and crystal plasticity. Dislocation densities (ranging from≈3·1012 m−2 to ≈3·1013 m−2) and twin line densities (≈22mm−1–165mm−1) are used as paleo-piezometers. The corresponding estimates of differential stresses vary between 33 and 132MPa, deduced from dislocation density and 92–251MPa obtained from twin density, possibly reflecting chronologically different maximum stress states and/or grain scale stress perturbations. Mean values of stress estimates are 68±46MPa and 168±60MPa, respectively, where estimates from dislocation density may represent a lower bound and those from twin density an upper bound. The stress estimates are also compatible with residual lattice strains determined with microfocus Laue diffraction yielding equivalent stresses of 50–300MPa in twinned calcite. The lower stress bound agrees with stress estimates from borehole breakout measurements performed in the pilot hole. From these data and assuming hydrostatic pore pressure and a low intermediate principal stress close to the overburden stress, frictional sliding of the San Andreas Fault at the SAFOD site is constrained to friction coefficients between 0.24 and 0.31. These low friction values may be related to the presence of clays, talc, and amorphous phases found in the fault cores and support the hypothesis of a weak San Andreas Fault. [Copyright &y& Elsevier]

Published

2011

29. Chemical and isotope compositions of drilling mud gas from the San Andreas Fault Observatory at Depth (SAFOD) boreholes: Implications on gas migration and the permeability structure of the San Andreas Fault

Author

Wiersberg, Thomas and Erzinger, Jörg

Subjects

*GAS analysis, *ISOTOPES, *MUD, *GEOLOGIC faults, *GEOCHEMISTRY

Abstract

Abstract: In this contribution we present results from two individual gas monitoring experiments which were conducted during the drilling of the SAFOD (San Andreas Fault Observatory at Depth) boreholes. Gas from circulating drilling mud was monitored during the drilling the SAFOD III side tracks and was later analyzed for δ13C (CH4, C2H6 and C3H8), H/D (CH4) and noble gas isotopes. Furthermore, gas accumulations induced by drill pipe retrieval (“trip gas”) from the SAFOD MH and the SAFOD III boreholes were also investigated. The data are interpreted in the context of gas migration processes and the permeability structure of the San Andreas Fault (SAF) around two actively deforming zones at 3194m and 3301m borehole depth. Helium isotope ratios of 0.86 Ra at 3203m and between 0.51 and 0.88 Ra at 3262m (Ra is the atmospheric 3He/4He ratio) indicate an improved flow of mantle volatiles between both fault strands. Much lower values were observed at 3147m (0.26 Ra) and 3312m (0.22 Ra). Hydrocarbon concentrations coincide with the occurrence of shale at ~3150–3200m and below ~3310m depth. The molecular and isotope composition of hydrocarbons and their spatial distributions imply hydrocarbon generation by thermal degradation of organic matter followed by extensive diffusion loss. Carbon isotope data furthermore suggest a thermal maturity of the source rock of approx. 1.4%R0. The concentration of trip gas is generally low in the interval 3100m–3450m but exhibits high spatial variability. At 3128m and 3223m depth, the trip gas concentrations are as low as in the granite section of the SAFOD Main Hole. Considerable variations of Ra values, trip gas concentrations, and the molecular composition of hydrocarbons when penetrating the active fault strands let us conclude that the permeability of the fault transverse to the fault direction is limited and that the active fault has not been breached over many earthquake cycles such that little or no fluid exchange took place. Diffusion is the dominant mechanism controlling hydrocarbon migration through the fault strands. The elevated Ra values between both fault strands may reflect either episodic or continuous flow of mantle-derived fluids, suggestive of some limited permeability parallel to the fault direction. [Copyright &y& Elsevier]

Published

2011

30. Fault rocks from the SAFOD core samples: Implications for weakening at shallow depths along the San Andreas Fault, California

Author

Holdsworth, R.E., van Diggelen, E.W.E., Spiers, C.J., de Bresser, J.H.P., Walker, R.J., and Bowen, L.

Subjects

*GEOLOGIC faults, *CALCITE, *ANHYDRITE, *PHYLLOSILICATES, *SEDIMENTS, *CORE materials

Abstract

Abstract: The drilling of a deep borehole across the actively creeping Parkfield segment of the San Andreas Fault Zone (SAFZ), California, and collection of core materials permit direct geological study of fault zone processes at 2–3 km depth. The three drill cores sample both host and fault rocks and pass through two currently active, narrow (1–2 m wide) shear zones enclosed within a broader (ca. 240 m wide) region of inactive foliated gouges. The host rocks preserve primary sedimentary features and are cut by numerous minor faults and small, mainly calcite-filled veins. The development of Fe-enriched smectitic phyllosilicate networks following cataclasis is prevalent in the presently inactive foliated gouges of the main fault zone and in minor faults cutting clay-rich host rocks. Calcite, anhydrite and minor smectitic phyllosilicate veins are interpreted to have formed due to local fluid overpressuring events prior to, synchronous with and after local gouge development. By contrast, the active shear zone gouges lack mineral veins (except as clasts) and contain numerous clasts of serpentinite. Markedly Mg-rich smectitic phyllosilicates are the dominant mineral phases here, suggesting that the fault zone fluids have interacted with the entrained serpentinites. We propose that weakening of the SAFZ down to depths of at least 3 km can be attributed to the pervasive development of interconnected networks of low friction smectitic phyllosilicates and to the operation of stress-induced solution-precipitation creep mechanisms. [ABSTRACT FROM AUTHOR]

Published

2011

31. Nanoscale porosity in SAFOD core samples (San Andreas Fault)

Author

Janssen, Christoph, Wirth, Richard, Reinicke, Andreas, Rybacki, Erik, Naumann, Rudolf, Wenk, Hans-Rudolf, and Dresen, Georg

Subjects

*POROSITY, *NANOCHEMISTRY, *TRANSMISSION electron microscopy, *FOCUSED ion beams, *MERCURY, *DEFORMATIONS (Mechanics), *FLUIDS, *ADSORPTION (Chemistry), *PERMEABILITY

Abstract

Abstract: With transmission electron microscopy (TEM) we observed nanometer-sized pores in four ultracataclastic and fractured core samples recovered from different depths of the main bore hole of the San Andreas Fault Observatory at Depth (SAFOD). Cutting of foils with a focused ion beam technique (FIB) allowed identifying porosity down to the nm scale. Between 40 and 50% of all pores could be identified as in-situ pores without any damage related to sample preparation. The total porosity estimated from TEM micrographs (1–5%) is comparable to the connected fault rock porosity (2.8–6.7%) estimated by pressure-induced injection of mercury. Permeability estimates for cataclastic fault rocks are 10−21–10−19 m2 and 10−17 m2 for the fractured fault rock. Porosity and permeability are independent of sample depth. TEM images reveal that the porosity is intimately linked to fault rock composition and associated with deformation. The TEM-estimated porosity of the samples increases with increasing clay content. The highest porosity was estimated in the vicinity of an active fault trace. The largest pores with an equivalent radius>200nm occur around large quartz and feldspar grains or grain-fragments while the smallest pores (equivalent radius<50nm) are typically observed in the extremely fine-grained matrix (grain size<1μm). Based on pore morphology we distinguish different pore types varying with fault rock fabric and alteration. The pores were probably filled with formation water and/or hydrothermal fluids at elevated pore fluid pressure, preventing pore collapse. The pore geometry derived from TEM observations and BET (Brunauer, Emmett and Teller) gas adsorption/desorption hysteresis curves indicates pore blocking effects in the fine-grained matrix. Observations of isolated pores in TEM micrographs and high pore body to pore throat ratios inferred from mercury injection suggest elevated pore fluid pressure in the low permeability cataclasites, reducing shear strength of the fault. [Copyright &y& Elsevier]

Published

2011

32. On the origin of mixed-layered clay minerals from the San Andreas Fault at 2.5–3 km vertical depth (SAFOD drillhole at Parkfield, California).

Author

Schleicher, A. M., Warr, L. N., and van der Pluijm, B. A.

Subjects

MINERALOGICAL chemistry, MINERALOGY, ROCK-forming minerals, GEOLOGIC faults, FLUID mechanics, CRYSTALLIZATION

Abstract

A detailed mineralogical study is presented of the matrix of mudrocks sampled from spot coring at three key locations along the San Andreas Fault Observatory at depth (SAFOD) drill hole. The characteristics of authigenic illite–smectite (I–S) and chlorite–smectite (C–S) mixed-layer mineral clays indicate a deep diagenetic origin. A randomly ordered I–S mineral with ca. 20–25% smectite layers is one of the dominant authigenic clay species across the San Andreas Fault zone (sampled at 3,066 and 3,436 m measured depths/MD), whereas an authigenic illite with ca. 2–5% smectite layers is the dominant phase beneath the fault (sampled at 3,992 m MD). The most smectite-rich mixed-layered assemblage with the highest water content occurs in the actively deforming creep zone at ca. 3,300–3,353 m (true vertical depth of ca. 2.7 km), with I–S (70:30) and C–S (50:50). The matrix of all mudrock samples show extensive quartz and feldspar (both plagioclase and K-feldspar) dissolution associated with the crystallization of pore-filling clay minerals. However, the effect of rock deformation in the matrix appears only minor, with weak flattening fabrics defined largely by kinked and fractured mica grains. Adopting available kinetic models for the crystallization of I–S in burial sedimentary environments and the current borehole depths and thermal structure, the conditions and timing of I–S growth can be evaluated. Assuming a typical K+ concentration of 100–200 ppm for sedimentary brines, a present-day geothermal gradient of 35°C/km and a borehole temperature of ca. 112°C for the sampled depths, most of the I–S minerals can be predicted to have formed over the last 4–11 Ma and are probably still in equilibrium with circulating fluids. The exception to this simple burial pattern is the occurrence of the mixed layered phases with higher smectite content than predicted by the burial model. These minerals, which characterize the actively creeping section of the fault and local thin film clay coating on polished brittle slip surfaces, can be explained by the influence of either cooler fluids circulating along this segment of the fault or the flow of K+-depleted brines. [ABSTRACT FROM AUTHOR]

Published

2009

33. Mineralogic and textural analyses of drill cuttings from the San Andreas Fault Observatory at Depth (SAFOD) boreholes: Initial interpretations of fault zone composition and constraints on geologic models.

Author

Bradbury, K. K., Barton, D. C., Solum, J. G., Draper, S. D., and Evans, J. P.

Subjects

*MINERALOGY, *BOREHOLE gravimetry, *GRAVIMETRY, *FAULT zones

Abstract

We examine drill cuttings from the San Andreas Fault Observatory at Depth (SAFOD) boreholes to determine the lithology and deformational textures in the fault zones and host rocks. Cutting samples represent the lithologies from 1.7-km map distance and 3.2-km vertical depth adjacent to the San Andreas Fault. We analyzed two hundred and sixty-six grain-mount thin-sections at an average of 30-m-cuttings sample spacing from the vertical 2.2-km-deep Pilot Hole and the 3.99-km-long Main Hole. We identify Quaternary and Tertiary(?) sedimentary rocks in the upper 700 m of the holes; granitic rocks from 760–1920 m measured depth; arkosic and lithic arenites, interbedded with siltstone sequences, from 1920 to ∼3150 m measured depth; and interbedded siltstones, mudstones, and shales from 3150 m to 3987 m measured depth. We also infer the presence of at least five fault zones, which include regions of damage zone and fault core on the basis of percent of cataclasite abundances, presence of deformed grains, and presence of alteration phases at 1050, 1600–2000, 2200–2500, 2700–3000, 3050–3350, and 3500 m measured depth in the Main Hole. These zones are correlated with borehole geophysical signatures that are consistent with the presence of faults. If the deeper zones of cataclasite and alteration intensity connect to the surface trace of the San Andreas Fault, then this fault zone dips 80–85° southwest, and consists of multiple slip surfaces in a damage zone ∼250–300 m thick. This interpretation is supported by borehole geophysical studies, which show this area is a region of low seismic velocities, reduced resistivity, and variable porosity. [ABSTRACT FROM AUTHOR]

Published

2007

34. SAFOD Penetrates the San Andreas Fault

Author

Mark D. Zoback

Subjects

SAFOD, Geology, QE1-996.5

Abstract

SAFOD, the San Andreas Fault Observatory at Depth (Fig. 1), completed an important milestone in July 2005 by drilling through the San Andreas Fault at seismogenic depth. SAFOD is one of three major components of EarthScope, a U.S. National Science Foundation (NSF) initiative being conducted in collaboration with the U.S. Geological Survey (USGS). The International Continental Scientific DrillingProgram (ICDP) provides engineering and technical support for the project as well as online access to project data and information (http://www.icdp-online.de/sites/sanandreas/news/news1.html). In 2002, the ICDP, the NSF, and the USGS provided funding for a pilot hole project at the SAFOD site. Twenty scientifi c papers summarizing the results of the pilot hole project as well as pre-SAFOD site characterization studies were published in Geophysical Research Letters (Vol.31, Nos. 12 and 15, 2004).

Published

2006

35. Electron Microscopy of Clay Minerals in Mudrocks from the San Andreas Fault Observatory at Depth (SAFOD)

Author

Schleicher, A., van der Pluijm, B., Warr, L., and Solum, J.

Subjects

lcsh:Geology, Mechanical Engineering, lcsh:QE1-996.5, Energy Engineering and Power Technology, SAFOD

Abstract

No abstract available. doi:10.2204/iodp.sd.s01.33.2007

Published

2018

36. Composition, Alteration, and Texture of Fault-Related Rocks from Safod Core and Surface Outcrop Analogs: Evidence for Deformation Processes and Fluid-Rock Interactions

Author

Susanne U. Janecke, Colter R. Davis, Kelly K. Bradbury, John W. Shervais, James Evans, and Birkhauser Verlag AG

Subjects

geography, geography.geographical_feature_category, Cataclasite, Outcrop, San Andreas fault, Geochemistry, core, Geology, Fault (geology), San Andreas Fault Observatory at Depth, hydrocarbon-bearing fluids, Geophysics, Geochemistry and Petrology, Fault gouge, Earth Sciences, Physical Sciences and Mathematics, Coast Range Ophiolite, damage zone, SAFOD, Shear zone, Protolith, Seismology, geochemistry

Abstract

We examine the fine-scale variations in mineralogical composition, geochemical alteration, and texture of the fault-related rocks from the Phase 3 whole-rock core sampled between 3,187.4 and 3,301.4 m measured depth within the San Andreas Fault Observatory at Depth (SAFOD) borehole near Parkfield, California. This work provides insight into the physical and chemical properties, structural architecture, and fluid-rock interactions associated with the actively deforming traces of the San Andreas Fault zone at depth. Exhumed outcrops within the SAF system comprised of serpentinite-bearing protolith are examined for comparison at San Simeon, Goat Rock State Park, and Nelson Creek, California. In the Phase 3 SAFOD drillcore samples, the fault-related rocks consist of multiple juxtaposed lenses of sheared, foliated siltstone and shale with block-in-matrix fabric, black cataclasite to ultracataclasite, and sheared serpentinite-bearing, finely foliated fault gouge. Meters-wide zones of sheared rock and fault gouge correlate to the sites of active borehole casing deformation and are characterized by scaly clay fabric with multiple discrete slip surfaces or anastomosing shear zones that surround conglobulated or rounded clasts of compacted clay and/or serpentinite. The fine gouge matrix is composed of Mg-rich clays and serpentine minerals (saponite ± palygorskite, and lizardite ± chrysotile). Whole-rock geochemistry data show increases in Fe-, Mg-, Ni-, and Cr-oxides and hydroxides, Fe-sulfides, and C-rich material, with a total organic content of >1 % locally in the fault-related rocks. The faults sampled in the field are composed of meters-thick zones of cohesive to non-cohesive, serpentinite-bearing foliated clay gouge and black fine-grained fault rock derived from sheared Franciscan Formation or serpentinized Coast Range Ophiolite. X-ray diffraction of outcrop samples shows that the foliated clay gouge is composed primarily of saponite and serpentinite, with localized increases in Ni- and Cr-oxides and C-rich material over several meters. Mesoscopic and microscopic textures and deformation mechanisms interpreted from the outcrop sites are remarkably similar to those observed in the SAFOD core. Micro-scale to meso-scale fabrics observed in the SAFOD core exhibit textural characteristics that are common in deformed serpentinites and are often attributed to aseismic deformation with episodic seismic slip. The mineralogy and whole-rock geochemistry results indicate that the fault zone experienced transient fluid–rock interactions with fluids of varying chemical composition, including evidence for highly reducing, hydrocarbon-bearing fluids.

Published

2014

37. A GIS-based method for archival and visualization of microstructural data from drill core samples.

Author

Holmes, Elliott

Subjects

Geographic information systems (GIS), spatial analysis, structural geology, remote sensing, microstructural data, SAFOD, Databases and Information Systems, Geology, Geophysics and Seismology

Abstract

Core samples obtained from scientific drilling could provide large volumes of direct microstructural and compositional data, but generating results via the traditional treatment of such data is often time-consuming and inefficient. Unifying microstructural data within a spatially referenced Geographic Information System (GIS) environment provides an opportunity to readily locate, visualize, correlate, and explore the available microstructural data. Using 26 core billet samples from the San Andreas Fault Observatory at Depth (SAFOD), this study developed procedures for: 1. A GIS-based approach for spatially referenced visualization and storage of microstructural data from drill core billet samples; and 2. Producing 3D models of sample billets and thin section positions within each billet, which serve as a digital record after irreversible material loss and fragmentation of physical billets. This approach permits spatial registration of 2D thin section ‘base maps’ within the core sample billets, where each billet is represented by 3D solid surface (produced via SFM photogrammetry) and internal structure models (acquired with micro-CT scans) created prior to sectioning. The spatial positions of the base maps were established within locally defined coordinate systems in each core billet’s solid surface model. The GIS database structure provided interactive linkage to the results of various analyses performed throughout the map at a wide range of scales (e.g. SEM and CL images as well as text and numerical data) within each thin section. The viability of the proposed framework was demonstrated via display of integrated microstructural data, creation of vector point information associated with features of interest in CL imagery, and development of a model for extraction and unsupervised classification of a multi-generation calcite vein network from the CL imagery. The results indicate that a GIS can facilitate the spatial treatment of 2D and 3D data even at centimeter to nanometer scales, building upon existing work which is predominantly limited to the 2D space of single thin sections. Conversely, the research effort also revealed several challenges, particularly involving intensive 3D representations and complex matrix transformations required to create geographically translated forms of the within-billet coordinate systems, which are suggested for consideration in future studies.

Published

2020

38. Fault rocks from the SAFOD core samples: Implications for weakening at shallow depths along the San Andreas Fault, California

Author

Robert E. Holdsworth, J. H. P. De Bresser, Richard Walker, E. W. E. van Diggelen, Christopher J. Spiers, and Leon Bowen

Subjects

geography, geography.geographical_feature_category, Anhydrite, Aardwetenschappen, Drilling, Geology, Cataclastic rock, Fault (geology), San Andreas Fault Observatory at Depth, chemistry.chemical_compound, chemistry, Phyllosilicate, Clastic rock, Fault zone weakening, San Andreas Fault, Fluid-assisted alteration, Sedimentary rock, SAFOD, Smectite, Shear zone, Petrology, Seismology

Abstract

The drilling of a deep borehole across the actively creeping Parkfield segment of the San Andreas Fault Zone (SAFZ), California, and collection of core materials permit direct geological study of fault zone processes at 2–3 km depth. The three drill cores sample both host and fault rocks and pass through two currently active, narrow (1–2 m wide) shear zones enclosed within a broader (ca. 240 m wide) region of inactive foliated gouges. The host rocks preserve primary sedimentary features and are cut by numerous minor faults and small, mainly calcite-filled veins. The development of Fe-enriched smectitic phyllosilicate networks following cataclasis is prevalent in the presently inactive foliated gouges of the main fault zone and in minor faults cutting clay-rich host rocks. Calcite, anhydrite and minor smectitic phyllosilicate veins are interpreted to have formed due to local fluid overpressuring events prior to, synchronous with and after local gouge development. By contrast, the active shear zone gouges lack mineral veins (except as clasts) and contain numerous clasts of serpentinite. Markedly Mg-rich smectitic phyllosilicates are the dominant mineral phases here, suggesting that the fault zone fluids have interacted with the entrained serpentinites. We propose that weakening of the SAFZ down to depths of at least 3 km can be attributed to the pervasive development of interconnected networks of low friction smectitic phyllosilicates and to the operation of stress-induced solution-precipitation creep mechanisms.

Published

2011

39. Structure and Properties of the San Andreas Fault in Central California: Recent Results from the SAFOD Experiment

Author

S. Hickman, M. Zoback, W. Ellsworth, N. Boness, P. Malin, S. Roecker, and C. Thurber

Subjects

lcsh:Geology, Mechanical Engineering, lcsh:QE1-996.5, Energy Engineering and Power Technology, SAFOD

Abstract

No abstract available. doi:10.2204/iodp.sd.s01.39.2007

Published

2007

40. Monitoring of Rock Mass Behavior at the Closest Proximity to Hypocenters in South African Gold Mines

Author

Ogasawara, H. and the Research Group for Semi-controlled Earthquake-Generation Experiments in South African Deep Gold Mines

Subjects

lcsh:Geology, lcsh:QE1-996.5, SAFOD

Abstract

No abstract available. doi:10.2204/iodp.sd.s01.11.2007

Published

2007

41. San Andreas Fault Zone Mineralogy, Geochemistry, and Physical Properties from SAFOD Cuttings and Core

Author

J. G. Solum, S. Hickman, D. A. Lockner, S. Tembe, J. Pl Evans, S. D. Draper, D. C. Barton, D. L. Kirschner, J. S. Chester, F. M. Chester, B. A. van der Pluijm, A. M. Schleicher, D. E. Moore, C. Morrow, K. Bradbury, W. M. Calvin, and T.-F. Wong

Subjects

lcsh:Geology, Mechanical Engineering, lcsh:QE1-996.5, Energy Engineering and Power Technology, SAFOD

Abstract

No abstract available. doi:10.2204/iodp.sd.s01.34.2007

Published

2007

42. SAFOD Phase III Core Sampling and Data Management at the Gulf Coast Repository

Author

Bradley A. Weymer, Firth, J., Rumford, P., Chester, F., Chester, J., and Lockner, D.

Subjects

lcsh:Geology, Mechanical Engineering, lcsh:QE1-996.5, Energy Engineering and Power Technology, SAFOD

Abstract

The San Andreas Fault Observatory at Depth (SAFOD)project is yielding new insight into the San Andreas Fault (Zoback et al., 2010; Zoback et al., this issue). SAFOD drilling started in 2002 with a pilot hole, and proceeded with three phrases of drilling and coring during the summers of 2004, 2005, and 2007 (Fig. 1). One key component of theproject is curation, sampling, and documentation of SAFOD core usage at the Integrated Ocean Drilling Program’s (IODP) Gulf Coast Repository (GCR) at Texas A&M University. We present here the milestones accomplished over the past two years of sampling Phase III core at the GCR.

Published

2011

43. Faulting processes in active faults – Evidences from TCDP and SAFOD drill core samples

Author

H. R. Wenk, Richard Wirth, Sheng-Rong Song, Luiz F. G. Morales, Christoph Janssen, Rudolf Naumann, M. Kienast, and Georg Dresen

Subjects

Geochemistry & Geophysics, geography, geography.geographical_feature_category, EBSD, Mineralogy, Drilling, Fault rock composition, Geology, Slip (materials science), Active fault, Fault (geology), Fault gouge, Comminution, SAFOD, Microstructures, Quartz, TCDP, CPO, Seismology, Electron backscatter diffraction

Abstract

The microstructures, mineralogy and chemistry of representative samples collected from the cores of the San Andreas Fault drill hole (SAFOD) and the Taiwan Chelungpu-Fault Drilling project (TCDP) have been studied using optical microscopy, TEM, SEM, XRD and XRF analyses. SAFOD samples provide a transect across undeformed host rock, the fault damage zone and currently active deforming zones of the San Andreas Fault. TCDP samples are retrieved from the principal slip zone (PSZ) and from the surrounding damage zone of the Chelungpu Fault. Substantial differences exist in the clay mineralogy of SAFOD and TCDP fault gouge samples. Amorphous material has been observed in SAFOD as well as TCDP samples. In line with previous publications, we propose that melt, observed in TCDP black gouge samples, was produced by seismic slip (melt origin) whereas amorphous material in SAFOD samples was formed by comminution of grains (crush origin) rather than by melting. Dauphiné twins in quartz grains of SAFOD and TCDP samples may indicate high seismic stress. The differences in the crystallographic preferred orientation of calcite between SAFOD and TCDP samples are significant. Microstructures resulting from dissolution-precipitation processes were observed in both faults but are more frequently found in SAFOD samples than in TCDP fault rocks. As already described for many other fault zones clay-gouge fabrics are quite weak in SAFOD and TCDP samples. Clay-clast aggregates (CCAs), proposed to indicate frictional heating and thermal pressurization, occur in material taken from the PSZ of the Chelungpu Fault, as well as within and outside of the SAFOD deforming zones, indicating that these microstructures were formed over a wide range of slip rates. © 2014 Elsevier Ltd.

Published

2014

44. Physico-chemical processes in seismogenic faults : active and exhumed examples

Author

Mittempergher, Silvia, Laboratoire de Géophysique Interne et Tectonophysique (LGIT), Observatoire des Sciences de l'Univers de Grenoble (OSUG), Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Université Joseph Fourier - Grenoble 1 (UJF)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Institut polytechnique de Grenoble - Grenoble Institute of Technology (Grenoble INP)-Institut national de recherche en sciences et technologies pour l'environnement et l'agriculture (IRSTEA)-Université Joseph Fourier - Grenoble 1 (UJF)-Institut national des sciences de l'Univers (INSU - CNRS)-Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes (UGA)-Laboratoire Central des Ponts et Chaussées (LCPC)-Institut des Sciences de la Terre (ISTerre), Université Grenoble Alpes (UGA)-Centre National de la Recherche Scientifique (CNRS)-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-PRES Université de Grenoble-Institut de recherche pour le développement [IRD] : UR219-Institut national des sciences de l'Univers (INSU - CNRS)-Institut Français des Sciences et Technologies des Transports, de l'Aménagement et des Réseaux (IFSTTAR)-Université Joseph Fourier - Grenoble 1 (UJF)-Centre National de la Recherche Scientifique (CNRS)-PRES Université de Grenoble-Institut de recherche pour le développement [IRD] : UR219-Institut Français des Sciences et Technologies des Transports, de l'Aménagement et des Réseaux (IFSTTAR), Laboratoire de Géophysique Interne et Tectonophysique, Université de Grenoble, Jean-Pierre Grattier, Giulio Di Toro, Institut des Sciences de la Terre (ISTerre), Université Joseph Fourier - Grenoble 1 (UJF)-Institut Français des Sciences et Technologies des Transports, de l'Aménagement et des Réseaux (IFSTTAR)-Institut national des sciences de l'Univers (INSU - CNRS)-Institut de recherche pour le développement [IRD] : UR219-PRES Université de Grenoble-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS), 127 Universita di Padova, Jean-Pierre Gratier, and Centre National de la Recherche Scientifique (CNRS)-PRES Université de Grenoble-Université Joseph Fourier - Grenoble 1 (UJF)-Institut Français des Sciences et Technologies des Transports, de l'Aménagement et des Réseaux (IFSTTAR)-Institut national des sciences de l'Univers (INSU - CNRS)-Institut de recherche pour le développement [IRD] : UR219-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])

Subjects

Seismic cycle, Fault rocks, Pressure-solution, Roches de failles, [SDU.STU]Sciences of the Universe [physics]/Earth Sciences, SAFOD, Microstructures, Fluid-rock interaction, Cycle sismique, Interaction fluids-roches

Abstract

The time recurrence of earthquakes is the result of the feedback between the tectonic loading and the evolution of fault strength during the seicmic cycle. This thesis aims to identify the chemical and physical processes in fault rocks from the modern seismogenic San Andreas Fault (California, USA) and the ancient seismogenic Gole Larghe Fault (Southern Alps, Italy). The San Andreas Fault was drilled to 2.7 km depth, and samples were extracted from the depth of nucleation of repeating microearthquakes. A cyclic recurrence of pressure-solution creep – hydrofracture - pressure solution creep supports the idea that isolated compartments of high fluid pressure might cause the nucleation of small to moderate size earthquakes, associated with the dominant creeping activity in this fault segment. The Gole Larghe Fault Zone was active 30 Ma ago at 9 – 11 km depth. The occurrence of pseudotachylytes witnesses its seismic behavior. Two topics were investigated: (i) The fabric evolution of cataclastic rocks with increasing deformation, to identify the processes potentially leading to the onset of unstable slip at the early stages of fault growth. (ii) The origin of fluids involved in seismic faulting and frictional melting. The formation of a cataclastic fault network allows the ingression of external hydrous fluids, probably of deep origin. The similar isotopic composition of natural pseudotachylytes and pseudotachylytes produced in dry conditions suggests that the fluid source is the dehydration of OH-bearing minerals in the wall rocks induced by coseismic frictional heating.; Les processus physiques et chimiques activés pendant le cycle sismique déterminent l'évolution des propriétés mécaniques des failles, à court terme (pendant un séisme) comme à long terme (la récupération des propretés élastiques des roches de faille après un seisme). L'étude des roches de faille naturelles est un moyen pour identifier les processus actives pendant les diverses phases des cycle séismique. En cette thèse, échantillons prévenants de deux failles séismiques sont étudiés: la Faille de San Andreas (California, USA), une faille séismique active, et la faille de Gole Larghe (Alpes Méridionales, Italie), une faille séismique exhumée. La Faille de San Andreas a été forée jusqu'à 2.7km de profondeur. Les échantillons montrent une superposition de: pression-dissolution - hydrofracturation - pression dissolution. La succession des évents est compatible avec la formation de sacs de fluides dans zones de basse perméabilité dans la faille, ou la pression de fluides augmente à cause de le progressif compactage de le gouge de faille, jusqu'à la nucléation de une rupture. La faille de Gole Larghe est une faille exhumée, qui a préservé des pseudotachylytes (roches fondues par le chaleur de friction pendant une frottement séismique) formées à 9 - 11 km de profondeur il y a 30 millions d'années. Deux argumentes sont traités: (i) l'évolution des microstructures des cataclasites associées à les pseudotachylytes, pour identifier les processus qui peuvent porter à la formation de instabilités frictionnelles pendant les premières phases de croissance de une faille. (ii) L'origine des fluides en failles séismiques et pendant la fusion pour friction. La formation de un système de failles à cataclasites permit la percolation de un fluide aqueux de profondeur. La composition isotopique des pseudotachylytes (calculé sans la component de hydratation) est proche à celle des pseudotachylytes reproduites en expériences du laboratoire (sans fluides). La principale source de fluides pendant la fusion pour friction est donc la déshydratation des minéraux hydraté des roches autour de la faille.

Published

2012

45. A microstructural study of fault rocks from the SAFOD: Implications for the deformation mechanisms and strength of the creeping segment of the San Andreas Fault

Author

Silvia Mittempergher, Jean-Pierre Gratier, J. Hadizadeh, Giulio Di Toro, Julie Richard, Hassan A. Babaie, and François Renard

Subjects

Earthquake, 010504 meteorology & atmospheric sciences, fault mechanics, Cataclastic rock, Slip (materials science), Fault (geology), 010502 geochemistry & geophysics, 01 natural sciences, Cataclasis, Foliated gouge, San Andreas Fault, Pressure solution, fault rocks, SAFOD, Shear localization, 0105 earth and related environmental sciences, Shearing (physics), geography, geography.geographical_feature_category, Geology, San Andreas Fault Observatory at Depth, Deformation mechanism, Shear (geology), Shear zone, Seismology

Abstract

The San Andreas Fault zone in central California accommodates tectonic strain by stable slip and microseismic activity. We study microstructural controls of strength and deformation in the fault using core samples provided by the San Andreas Fault Observatory at Depth (SAFOD) including gouge corresponding to presently active shearing intervals in the main borehole. The methods of study include high-resolution optical and electron microscopy, X-ray fluorescence mapping, X-ray powder diffraction, energy dispersive X-ray spectroscopy, white light interferometry, and image processing. The fault zone at the SAFOD site consists of a strongly deformed and foliated core zone that includes 2–3 m thick active shear zones, surrounded by less deformed rocks. Results suggest deformation and foliation of the core zone outside the active shear zones by alternating cataclasis and pressure solution mechanisms. The active shear zones, considered zones of large-scale shear localization, appear to be associated with an abundance of weak phases including smectite clays, serpentinite alteration products, and amorphous material. We suggest that deformation along the active shear zones is by a granular-type flow mechanism that involves frictional sliding of microlithons along phyllosilicate-rich Riedel shear surfaces as well as stress-driven diffusive mass transfer. The microstructural data may be interpreted to suggest that deformation in the active shear zones is strongly displacement-weakening. The fault creeps because the velocity strengthening weak gouge in the active shear zones is being sheared without strong restrengthening mechanisms such as cementation or fracture sealing. Possible mechanisms for the observed microseismicity in the creeping segment of the SAF include local high fluid pressure build-ups, hard asperity development by fracture-and-seal cycles, and stress build-up due to slip zone undulations.

Published

2012

46. Investigating the electrical conductivity structure of the San Andreas fault system in the Parkfield-Cholame region, central California, with 3D magnetotelluric inversion

Author

Tietze, Kristina

Subjects

3D inversion, non-volcanic tremors, Parkfield, 500 Naturwissenschaften und Mathematik::550 Geowissenschaften, Geologie, San Andreas fault, magnetotellurics, 550 - Earth sciences, SAFOD, electrical resistivity

Abstract

This thesis presents the application of 3D MT inversion to an array data set of more than 250 sites from central California to image the electrical conductivity structure of the San Andreas fault (SAF) system in the Parkfield- Cholame region where the fault changes its mechanical state. Previous extensive two-dimensional (2D) inversion revealed a high-conductivity region in the upper mantle and lower crust, which has a connection to the SAF in the northern, transitional-to-creeping section, whereas it is confined to lower- crustal to upper-mantle levels in the transitional-to-locked section. The highly conductive region and the connecting channel were interpreted as migration path for fluids rising from mantle depth into the SAF system where they are considered to contribute to the low-frictional strength of the creeping fault segment. The new 3D inversion results confirm the high- conductive zones of the 2D results and strongly support the presence of a fluid channel into the SAF system in the creeping segment. However, conductivity structures obtained with 3D inversion also showed a great non- uniqueness depending on the inversion setup. Satisfying models (in terms of data fit) could only be recovered if the inversion parameters were tuned in accordance with the particularities of the data set. Based on the Parkfield MT data and complementary synthetic 3D data sets, the model space was explored by testing the influences of a wide range of inversion settings. The results show that in presence of a pronounced regional 2D structure, 3D inversion of the complete impedance tensor still depends on the coordinate system. 2D subsurface structures can vanish if data are not aligned with the regional strike-direction. A priori models and data weighting, i.e. how strongly individual components of the impedance tensor and/or vertical magnetic field transfer functions dominate the solution, are crucial controls for the outcome of 3D inversion. If deviations from a prior model are heavily penalized, regularization is prone to result in erroneous and misleading 3D inversion models, particularly in the presence of strong conductivity contrasts. Reliable and meaningful 3D inversion models can only be recovered if data misfit is assessed systematically in the frequency-space domain. Galvanic distortion can impair 3D inversion models and result in spurious structures at depth. A new tool for automatic identification of static shift was developed and applied to synthetic and real world data, making use of the spatial coherence of MT responses. For the Parkfield data set, identification and removal of static shift improved the outcome of subsequent 3D inversion for the near-surface layers. Inversion of phase tensor and apparent resistivity & phase data was implemented into the 3D inversion scheme and proved to be a valuable asset for obtaining reliable subsurface images from galvanically distorted data, while not requiring any data preprocessing., In der vorliegenden Arbeit ist die Anwendung eines dreidimensionalen (3D) magnetotellurischen (MT) Inversionsschemas auf einen Array-Datensatz von mehr als 250 Stationen aus Zentralkalifornien (USA) dargestellt. Die Untersuchungen hatten zum Ziel, die elektrische Leitfähigkeitsstruktur der San Andreas- Verwerfung (SAF) in der Region zwischen Parkfield und Cholame, in der sich das mechanische Verhalten der Verwerfung ändert, abzubilden. Vorangegangene zweidimensionale (2D) Inversionen des Datensatzes zeigten eine Region hoher elektrischer Leitfähigkeit im Tiefenbereich des oberen Mantel und der unteren Kruste, die im nördlichen Teil des Messgebiets hin zum kriechenden Segment mit der seismogenen SAF verbunden ist. Im übergang zum blockierten Verwerfungsabschnitt Richtung Süden ist diese leitfähige Region in der Tiefe dagegen von der oberkrustalen Deformationszone abgeschnitten. Die Bereiche erhöhter Leitfähigkeit und die kanalartige Verbindung im Norden wurden als Migrationspfade für Fluide interpretiert, die aus dem Mantel in das SAF System aufsteigen. Es wird vermutet, dass Fluide wesentlich zur mechanischen Schwäche der SAF im kriechenden Segment beitragen. Die neuen, 3D Inversionsergebnisse bestätigen die elektrisch leitfähige Zone aus den 2D Modellen und unterstützen die Existenz eines Fluidkanals in das SAF-System im kriechenden Abschnitt. Jedoch zeigten die 3D Leitfähigkeitsmodelle starke Variationen der abgebildeten Strukturen, die mit der Wahl der Inversionsparameter zusammenhingen. Zufriedenstellende Modelle (im Sinne der Datenanpassung) konnten nur ermittelt werden, wenn die Inversionsparameter auf die Besonderheiten des Datensatzes abgestimmt waren. Basierend auf den MT-Daten aus Kalifornien sowie komplementären synthetischen 3D Datensätzen wurde der Einfluss der Inversionsparameter auf den Modellraum untersucht. Die Ergebnisse zeigen, dass die 3D Inversion in Gegenwart einer ausgeprägten, regionalen 2D Struktur von der Orientierung des Koordinatensystems abhängt, auch wenn alle vier Komponenten des Impedanztensors in der Inversion verwendet werden. 2D Untergrundstrukturen können gänzlich verschwinden, wenn das Koordinatensystem nicht an der regionalen geoelektrischen Streichrichtung ausgerichtet ist. A priori-Modelle und Datengewichtung, welche bestimmt, wie stark einzelne Komponenten des Impedanztensors und der vertikalen magnetischen übertragungsfunktionen die Lösung dominieren, sind wichtige Steuerungselemente für das 3D Inversionsergebnis. Werden Abweichungen von einem a priori-Modell stark regularisiert, führt dies leicht zu verfälschten und irreführenden 3D Inversionsergebnissen, insbesondere wenn starke Leitfähigkeitskontraste im Untergrund vorhanden sind. Verlässliche und aussagekräftige Modelle können nur ermittelt werden, wenn eine systematische Auswertung der Datenanpassung im Frequenz-Orts-Bereich vorgenommen wird. Galvanische Verzerrung von MT-Daten kann die Qualität von 3D Inversionsmodellen beeinträchtigen und zum Aufreten artifizieller Strukturen bis in gro\ss e Tiefe führen. Zur Identifizierung von Static Shift wurde ein neues Schema entwickelt, das auf der räumlichen Kohärenz von MT-Daten basiert, und sowohl auf synthetische als auch auf Messdaten angewendet. Für den Kalifornien-Datensatz verbesserte die Entfernung von Static Shift die nachfolgenden 3D Inversionsergebnisse. Die Inversionen von Phasentensoren und scheinbaren Widerständen & Phasen, die in das 3D Inversionspaket implementiert wurden, sind ein wertvoller Gewinn für die verlässliche Abbildung von Untergrundsstrukturen, ohne dafür verzerrte Daten vorbehandeln zu müssen.

Published

2012

47. Evidence of transient increases of fluid pressure in SAFOD phase III cores

Author

Mittempergher, Silvia, DI TORO, Giulio, Gratier JP, 2, Hadizadeh, J, Smith, Saf, Spiess, Richard, Mécanique des failles, Institut des Sciences de la Terre (ISTerre), Université Joseph Fourier - Grenoble 1 (UJF)-Institut Français des Sciences et Technologies des Transports, de l'Aménagement et des Réseaux (IFSTTAR)-Institut national des sciences de l'Univers (INSU - CNRS)-Institut de recherche pour le développement [IRD] : UR219-PRES Université de Grenoble-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS)-Université Joseph Fourier - Grenoble 1 (UJF)-Institut Français des Sciences et Technologies des Transports, de l'Aménagement et des Réseaux (IFSTTAR)-Institut national des sciences de l'Univers (INSU - CNRS)-Institut de recherche pour le développement [IRD] : UR219-PRES Université de Grenoble-Université Savoie Mont Blanc (USMB [Université de Savoie] [Université de Chambéry])-Centre National de la Recherche Scientifique (CNRS), Dipartimento di Geoscienze [Padova], Universita degli Studi di Padova, Istituto Nazionale di Geofisica e Vulcanologia - Sezione di Roma (INGV), Istituto Nazionale di Geofisica e Vulcanologia, Department of Geography and Geosciences [Louisville], University of Louisville, Grants: Padova University PhD scholarship (SM), CARIPARO project CD0504012134 (GDT), European Research Council Starting Grant Project 205175 (USEMS) (GDT and SAFS), INSU-C (JPG), Prin 2007BWMWM8 (RS). + Supported by the US National Science Foundation NFS-Earthscope 0545472 (JH, GDT)., and Università degli Studi di Padova = University of Padua (Unipd)

Subjects

fault rocks, role of fluids, 8045 Structural Geology: Role of fluids, 8030 Structural Geology: Microstructures, 8010 Structural Geology: Fractures and faults, microstructures, SAFOD, [SDU.STU.GM]Sciences of the Universe [physics]/Earth Sciences/Geomorphology, human activities

Abstract

6p.; International audience; The San Andreas Fault Observatory at Depth (SAFOD) in Parkfield, central California, has been drilled through a fault segment that is actively deforming through creep and microearthquakes. Creeping is accommodated in two fault strands, the Southwest and Central Deforming Zones, embedded within a damaged zone of deformed shale and siltstone. During drilling, no pressurized fluids have been encountered, even though the fault zone acts as a permeability barrier to fluid circulation between the North American and Pacific plates. Microstructural analysis of sheared shales associated with calcite and anhydrite-bearing veins found in SAFOD cores collected at 1.5m from the Southwest Deforming Zone, suggests that transient increases of pore fluid pressure have occurred during the fault activity, causing mode I fracturing of the rocks. Such build-ups in fluid pressure may be related to permeability reduction during fault creep and pressure-solution processes, resulting in localized failure of small fault zone patches and providing a potential mechanism for the initiation of some of the microearthquakes registered in the SAFOD site.

Published

2011

48. Rock Properties and Internal Structure of the San Andreas Fault Near ~ 3 km Depth in the SAFOD Borehole Based on Meso- to Micro-scale Analyses of Phase III Whole Rock Core

Author

Bradbury, Kelly Keighley and Evans, James P.

Subjects

safod, mesoscopic, Earth Sciences, Physical Sciences and Mathematics, san andreas fault, rock, borehole, Geology

Abstract

We examine the relationships between rock properties and structure within ~ 41 m of PHASE III whole-rock core collected from ~ 3 km depth along the SAF in the San Andreas Fault Observatory at Depth (SAFOD) borehole, near Parkfield, CA.

Published

2010

49. Composition and Structure of the San Andreas Fault Observatory at Depth (SAFOD) Phase III Whole-Rock Core: Implications for Fault Zone Deformation and Fluid-Rock Interactions

Author

Bradbury, Kelly Keighley and Evans, James P.

Subjects

composition, safod, fault zone, Earth Sciences, Physical Sciences and Mathematics, san andreas fault, Geology, fluid

Abstract

We examine the composition and texture of whole-rock core from ~ 3 km depth in the San Andreas Fault Observatory at Depth (SAFOD) borehole, which provides a unique opportunity to characterize in situ rock properties of the near-fault environment, and how these properties vary in an area where deformation is accommodated by aseismic creep and high-rates of microseismicity. Detailed petrography and microstructural analyses coupled with X-Ray Diffraction and X-ray Fluorescence techniques are used to describe composition, alteration, and textures. All samples record multiple generations of cataclastic deformation in a complexly deformed and altered sequence of fine-grained sheared rocks. Localized shears bound multi-layered zones of medium to ultra-fine grained cataclasite. Phacoidal clasts or porphyroclasts comprised of serpentinite, quartz, and older cataclasite are embedded within the comminuted phyllosilicate-rich gouge. The intensity of damage-related features and the development of a pervasive anastomosing fabric increases towards and within the two active slip zones near ~ 3192 and 3302 m MD. Foliated fabrics alternating with discrete fractures suggest a mixed-mode style of deformation including both ductile flow and brittle deformation processes during fault zone evolution. Deformation at high-strain rates is suggested by the presence of crack-seal veins in clasts, the presence of porphyroclasts, and the development of S-C fabrics in the phyllosilicate- rich gouge. Evidence for fluid-rock interaction across the fault zone is indicated by depletion of Si and enrichment of MgO, FeO, and CaO; with significant clay alteration and/or growth of neo-mineralized vein fillings and fracture surface coatings. Shear localization may decrease porosity and inhibit fluid flow whereas fracturing may locally facilitate fluid migration and/or chemical alteration within the fault zone. These results constrain hypotheses related to fault zone behavior and broaden our understanding of the processes controlling earthquake nucleation and/or energy adsorption within the SAF. Based on the similarity of our observations to previous results from surface exposures of the SAF, we emphasize the importance of exhumed fault zone studies as proxies for understanding deformation and seismicity in the shallow crust.

Published

2010

50. A microstructural study of fault rocks from the SAFOD: Implications for the deformation mechanisms and strength of the creeping segment of the San Andreas Fault

Author

Hadizadeh, J, Mittempergher, S, Gratier, J, Renard, F, Di Toro, G, Richard, J, Babaie, H, Gratier, JP, Babaie, HA, Hadizadeh, J, Mittempergher, S, Gratier, J, Renard, F, Di Toro, G, Richard, J, Babaie, H, Gratier, JP, and Babaie, HA

Abstract

The San Andreas Fault zone in central California accommodates tectonic strain by stable slip and microseismic activity. We study microstructural controls of strength and deformation in the fault using core samples provided by the San Andreas Fault Observatory at Depth (SAFOD) including gouge corresponding to presently active shearing intervals in the main borehole. The methods of study include high-resolution optical and electron microscopy, X-ray fluorescence mapping, X-ray powder diffraction, energy dispersive X-ray spectroscopy, white light interferometry, and image processing.The fault zone at the SAFOD site consists of a strongly deformed and foliated core zone that includes 2-3 m thick active shear zones, surrounded by less deformed rocks. Results suggest deformation and foliation of the core zone outside the active shear zones by alternating cataclasis and pressure solution mechanisms. The active shear zones, considered zones of large-scale shear localization, appear to be associated with an abundance of weak phases including smectite clays, serpentinite alteration products, and amorphous material. We suggest that deformation along the active shear zones is by a granular-type flow mechanism that involves frictional sliding of microlithons along phyllosilicate-rich Riedel shear surfaces as well as stress-driven diffusive mass transfer. The microstructural data may be interpreted to suggest that deformation in the active shear zones is strongly displacement-weakening. The fault creeps because the velocity strengthening weak gouge in the active shear zones is being sheared without strong restrengthening mechanisms such as cementation or fracture sealing. Possible mechanisms for the observed microseismicity in the creeping segment of the SAF include local high fluid pressure build-ups, hard asperity development by fracture-and-seal cycles, and stress build-up due to slip zone undulations.

Published

2012