Thermally induced shear reactivation of critically-stressed smooth and rough granite fractures

Abstract Many candidate geological repositories have been reported to have relatively high ratios of in-situ horizontal stress to vertical stress. There can be a substantial increase in the horizontal stress due to the thermal stress resulting from radioactive decay, and accordingly fractures – part...

Full description

Saved in:
Bibliographic Details
Published inIOP conference series. Earth and environmental science Vol. 1124; no. 1; pp. 12119 - 12126
Main Authors Sun, Changlun, Zhuang, Li, Yoon, Jeoung Seok, Min, Ki-Bok
Format Journal Article
LanguageEnglish
Published Bristol IOP Publishing 01.01.2023
Subjects
Correlation analysis
Digital imaging
Dilation
Fractures
Geology
Granite
Heating
Image processing
Mechanical loading
Permeability
Radioactive decay
Repositories
Shear
Slip
Surface roughness
Thermal stress
Transducers
Online AccessGet full text

Cover

More Information
Summary:Abstract Many candidate geological repositories have been reported to have relatively high ratios of in-situ horizontal stress to vertical stress. There can be a substantial increase in the horizontal stress due to the thermal stress resulting from radioactive decay, and accordingly fractures – particular the shallowly dipping ones – could be reactivated. The associated permeability increase with fracture shear dilation and large fracture slip could threaten the long-term safety of the deep geological repository. In this study, we elaborately investigated fracture reactivation under the coupled thermo-mechanical loading based on laboratory experiments. Critically-stressed single fractures in ca. 100 mm cubic granite specimens were heated in the minimum principal stress direction, through setting a target temperature of 150 °C at the heating source. Expansion in the maximum principal stress direction was restricted. Sawcut, laser-marking, and tensile-splitting fractures with low to high joint surface roughness (JRC=0~13) were compared. Fracture slip and shear dilation were directly measured by using clip-on displacement transducers and the measurements were further validated by the digital image correlation analysis. Temperature is non-uniformly distributed in the rock, and decreases with the increasing distance to the heating source. Thermally induced fracture slip grows slowly (compared with the stick-slip) but progressively with the peak slip rate of 2.69 – 6.65× 10 −2 μm/s in different test cases. Shear dilation during thermoshearing can be ignored in the sawcut fracture, and a tendency that shear dilation is higher for the fracture with a larger JRC was confirmed.
ISSN:1755-1307
1755-1315
DOI:10.1088/1755-1315/1124/1/012119