Kiyotoshi Sakaguchi scite author profile

Hydraulic fracturing experiments were conducted at 200–450°C by injecting water into cylindrical granite samples containing a borehole at an initial effective confining pressure of 40 MPa. Intensive fracturing was observed at all temperatures, but the fracturing characteristics varied with temperature, perhaps due to differences in the water viscosity. At the lowest considered temperature (200°C), fewer fractures propagated linearly from the borehole, and the breakdown pressure was twice the confining pressure. However, these characteristics disappeared with increasing temperature; the fracture pattern shifted toward the formation of a greater number of shorter fractures over the entire body of the sample, and the breakdown pressure decreased greatly. Hydraulic fracturing significantly increased the permeability at all temperatures, and this permeability enhancement was likely to form a productive geothermal reservoir even at the highest considered temperature, which exceeded both the brittle‐ductile transition temperature of granite and the critical temperature of water.

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Cloud-fracture networks as a means of accessing superhot geothermal energy

Watanabe

Sakaguchi

Goto

et al. 2019

Sci Rep

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Superhot geothermal environments (above ca. 400 °C) represent a new geothermal energy frontier. However, the networks of permeable fractures capable of storing and transmitting fluids are likely to be absent in the continental granitic crust. Here we report the first-ever experimental results for well stimulation involving the application of low-viscosity water to granite at temperatures ≥400 °C under true triaxial stress. This work demonstrates the formation of a network of permeable microfractures densely distributed throughout the entire rock body, representing a so-called cloud-fracture network. Fracturing was found to be initiated at a relatively low injection pressure between the intermediate and minimum principal stresses and propagated in accordance with the distribution of preexisting microfractures, independent of the directions of the principal stresses. This study confirms the possibility of well stimulation to create excellent fracture patterns that should allow the effective extraction of thermal energy.

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Estimation of closure of a fracture under normal stress based on aperture data

Matsuki

Wang

Giwelli

et al. 2008

International Journal of Rock Mechanics and Mining Sciences

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Creating Cloud-Fracture Network by Flow-induced Microfracturing in Superhot Geothermal Environments

et al. 2021

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Effect of shear displacement on the hydraulic conductivity of a fracture

Matsuki

Kimura

Sakaguchi

et al. 2010

International Journal of Rock Mechanics and Mining Sciences

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Time-dependent closure of a fracture with rough surfaces under constant normal stress

Matsuki

Wang

Sakaguchi

et al. 2001

International Journal of Rock Mechanics and Mining Sciences

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