Microscopic features of quartz and clay particles from fault gouges and infilled fractures in granite: Discriminating between active and inactive faulting

To assist in identifying faults that have a significant potential for displacement at or near the ground surface, we carried out in-depth investigations on fault gouges and a fracture infilled with clay (clay vein) in the Kojaku Granite on the Tsuruga Peninsula, central Japan. We sampled several fau...

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Bibliographic Details
Published in:Engineering geology 2016-08, Vol.210, p.180-196
Main Authors: Niwa, Masakazu, Shimada, Koji, Aoki, Kazuhiro, Ishimaru, Tsuneari
Format: Article
Language:English
Subjects:
Abrasion
Clay minerals
Electron microscopy
Fault gouge
Faults
Fracture mechanics
Granite
Quartz
Scanning electron microscopy
Transmission electron microscopy
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Summary:To assist in identifying faults that have a significant potential for displacement at or near the ground surface, we carried out in-depth investigations on fault gouges and a fracture infilled with clay (clay vein) in the Kojaku Granite on the Tsuruga Peninsula, central Japan. We sampled several fault gouges at different stages of evolutions and clay-rich infilling of a fracture with no evidence of offset. Based on our field observations, gouge in an active fault is characterized by 1) stacked layers of different colors made up of comminuted fragments and clays, and 2) injection of the fragments and clays from the gouge into the surrounding rocks, indicating an accumulation of seismic-induced shearing. Our thin-section observations and X-ray diffraction analyses show that all our samples are similar in the degree of fragmentation and mineral composition, and because of this, our study became focused mainly on microscopic features using laser diffraction particle size analysis, scanning electron microscopy (SEM), and transmission electron microscopy (TEM). We identified the mineralogical and textural characteristics of the samples in order to improve our ability to discriminate between active and inactive faulting. Particle size distribution analysis showed that the gouge in the active fault contains the greatest abundance of finer particles due to multiple slip events, which contrasts with the clay-rich infilling of a fracture. SEM examination of the quartz particles showed that the gouge in the active fault contains more particles that have retained sharp and smooth crystal surfaces (formed by fracturing) than do either the gouges in minor faults (that show no evidence of recent shear) or the clay-rich infilling of a fracture. In contrast, TEM observations of very fine clay minerals (approximately
ISSN:0013-7952
1872-6917
DOI:10.1016/j.enggeo.2016.06.013