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

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 (3141–3307 m MD), show a co...

Full description

Saved in:
Bibliographic Details
Published in:Tectonophysics 2011-08, Vol.509 (1), p.107-119
Main Authors: Rybacki, E., Janssen, C., Wirth, R., Chen, K., Wenk, H.-R., Stromeyer, D., Dresen, G.
Format: Article
Language:English
Subjects:
Asymptotic properties
Calcite
Density
Estimates
Faults
Microstructure
Piezometer
Residual strain
SAFOD
San Andreas Fault
Stress
Stresses
Veins
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary: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 (3141–3307 m 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 · 10 12 m − 2 to ≈ 3 · 10 13 m − 2 ) and twin line densities (≈ 22 mm − 1 –165 mm − 1 ) are used as paleo-piezometers. The corresponding estimates of differential stresses vary between 33 and 132 MPa, deduced from dislocation density and 92–251 MPa obtained from twin density, possibly reflecting chronologically different maximum stress states and/or grain scale stress perturbations. Mean values of stress estimates are 68 ± 46 MPa and 168 ± 60 MPa, 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 50–300 MPa 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. ► Microstructures of SAFOD core samples indicate intense shearing and dissolution–precipitation as main deformation processes. ► Calcite veins show evidence for twinning and crystal plasticity. ► Lower stress bound estimated from microstructure analysis agrees with stress estimates from borehole breakout measurements. ► Assuming hydrostatic pore pressure, the inferred friction coefficient is quite low. ► Microstructural analysis supports the hypothesis of a weak San Andreas Fault.
ISSN:0040-1951
1879-3266
DOI:10.1016/j.tecto.2011.05.014