A systematic model- and experimental approach to hydro-mechanical and thermo-mechanical fracture processes in crystalline rocks

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A systematic model- and experimental approach to hydro-mechanical and thermo-mechanical fracture processes in crystalline rocks. / Kolditz, Olaf; McDermott, Christopher; Yoon, Jeoung Seok et al.
In: Geomechanics for energy and the environment, Vol. 41.2025, No. March, 100616, 20.12.2024.

Research output: Contribution to journalArticleResearchpeer-review

Harvard

Kolditz, O, McDermott, C, Yoon, JS, Mollaali, M, Wang, W, Hu, M, Sasaki, T, Rutqvist, J, Birkholzer, J, Park, J-W, Park, C-H, Liu, H, Pan, PZ, Nagel, T, Nguyen, S, Kwon, S, Lee, C, Kim, K-I, Alexander, B, Hadgu, T, Wang, Y, Zhuang, L, Yoshioka, K, Cunha, GB & Fraser-Harris, A 2024, 'A systematic model- and experimental approach to hydro-mechanical and thermo-mechanical fracture processes in crystalline rocks', Geomechanics for energy and the environment, vol. 41.2025, no. March, 100616. https://doi.org/10.1016/j.gete.2024.100616

APA

Kolditz, O., McDermott, C., Yoon, J. S., Mollaali, M., Wang, W., Hu, M., Sasaki, T., Rutqvist, J., Birkholzer, J., Park, J.-W., Park, C.-H., Liu, H., Pan, PZ., Nagel, T., Nguyen, S., Kwon, S., Lee, C., Kim, K.-I., Alexander, B., ... Fraser-Harris, A. (2024). A systematic model- and experimental approach to hydro-mechanical and thermo-mechanical fracture processes in crystalline rocks. Geomechanics for energy and the environment, 41.2025(March), Article 100616. https://doi.org/10.1016/j.gete.2024.100616

Vancouver

Kolditz O, McDermott C, Yoon JS, Mollaali M, Wang W, Hu M et al. A systematic model- and experimental approach to hydro-mechanical and thermo-mechanical fracture processes in crystalline rocks. Geomechanics for energy and the environment. 2024 Dec 20;41.2025(March):100616. doi: 10.1016/j.gete.2024.100616

Author

Kolditz, Olaf ; McDermott, Christopher ; Yoon, Jeoung Seok et al. / A systematic model- and experimental approach to hydro-mechanical and thermo-mechanical fracture processes in crystalline rocks. In: Geomechanics for energy and the environment. 2024 ; Vol. 41.2025, No. March.

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@article{25b2911910424fefaac634761d4e23bc,
title = "A systematic model- and experimental approach to hydro-mechanical and thermo-mechanical fracture processes in crystalline rocks",
abstract = "The paper presents the key findings of Task G SAFENET of the DECOVALEX 2023 project “Safety Assessment of Fluid Flow, Shear, Thermal and Reaction Processes within Crystalline Rock Fracture NETworks”. It utilizes a systematic and experimental approach to numerically simulate mechanical (M), hydro-mechanical (HM), and thermo-mechanical (TM) fracture processes in brittle rocks. The Task team introduced, applied, and compared a wide range of numerical methods, including both continuum and discontinuum methods, for simulating related fracture processes. Task G is based on three key experiments: the Freiberg, GREAT cell, and KICT experiments, which analyze M, HM, and TM processes respectively. Classic HM and THM benchmark exercises serve as a common basis by using analytical solutions for a plane line discontinuity in a poro-elastic medium (Sneddon and Lowengrub, 1969) and a point heat source in a thermo-poro-elastic medium (Booker and Savvidou, 1985), (Chaudhry et al., 2019). These solutions also serve as a reference for rough fractures and simple fracture networks. A systematic set of new benchmark cases has been derived based on the GREAT cell experiments. An analysis of the constant normal load (CNL) experiment has been conducted using micro- and macroscopic approaches, based on the Freiberg experiment. The GREAT cell experiments provided a database for evaluating the mechanical and hydro-mechanical responses of various rock samples (resin, greywacke, gneis) in triaxial tests with a rotational stress field. Fracture permeability was determined as a function of normal stresses in the rotational stress field. The KICT experiments were used to investigate thermally induced shear slip and dilation processes. The SAFENET Task contributed to the Open Science concept in DECOVALEX by providing a freely accessible Jupyter notebooks for selected benchmark exercises.",
author = "Olaf Kolditz and Christopher McDermott and Yoon, {Jeoung Seok} and Mostafa Mollaali and Wenqing Wang and Mengsu Hu and Tsubasa Sasaki and Jonny Rutqvist and Jens Birkholzer and Jung-Wook Park and Chan-Hee Park and Hejuan Liu and Peng–Zhi Pan and Thomas Nagel and Son Nguyen and Saeha Kwon and Changsoo Lee and Kwang-Il Kim and Bond Alexander and Teklu Hadgu and Yifeng Wang and Li Zhuang and Keita Yoshioka and Cunha, {Gon{\c c}alo Benitez} and Andrew Fraser-Harris",
year = "2024",
month = dec,
day = "20",
doi = "10.1016/j.gete.2024.100616",
language = "English",
volume = "41.2025",
journal = "Geomechanics for energy and the environment",
issn = "2352-3808",
publisher = "Elsevier",
number = "March",

}

RIS (suitable for import to EndNote) - Download

TY - JOUR

T1 - A systematic model- and experimental approach to hydro-mechanical and thermo-mechanical fracture processes in crystalline rocks

AU - Kolditz, Olaf

AU - McDermott, Christopher

AU - Yoon, Jeoung Seok

AU - Mollaali, Mostafa

AU - Wang, Wenqing

AU - Hu, Mengsu

AU - Sasaki, Tsubasa

AU - Rutqvist, Jonny

AU - Birkholzer, Jens

AU - Park, Jung-Wook

AU - Park, Chan-Hee

AU - Liu, Hejuan

AU - Pan, Peng–Zhi

AU - Nagel, Thomas

AU - Nguyen, Son

AU - Kwon, Saeha

AU - Lee, Changsoo

AU - Kim, Kwang-Il

AU - Alexander, Bond

AU - Hadgu, Teklu

AU - Wang, Yifeng

AU - Zhuang, Li

AU - Yoshioka, Keita

AU - Cunha, Gonçalo Benitez

AU - Fraser-Harris, Andrew

PY - 2024/12/20

Y1 - 2024/12/20

N2 - The paper presents the key findings of Task G SAFENET of the DECOVALEX 2023 project “Safety Assessment of Fluid Flow, Shear, Thermal and Reaction Processes within Crystalline Rock Fracture NETworks”. It utilizes a systematic and experimental approach to numerically simulate mechanical (M), hydro-mechanical (HM), and thermo-mechanical (TM) fracture processes in brittle rocks. The Task team introduced, applied, and compared a wide range of numerical methods, including both continuum and discontinuum methods, for simulating related fracture processes. Task G is based on three key experiments: the Freiberg, GREAT cell, and KICT experiments, which analyze M, HM, and TM processes respectively. Classic HM and THM benchmark exercises serve as a common basis by using analytical solutions for a plane line discontinuity in a poro-elastic medium (Sneddon and Lowengrub, 1969) and a point heat source in a thermo-poro-elastic medium (Booker and Savvidou, 1985), (Chaudhry et al., 2019). These solutions also serve as a reference for rough fractures and simple fracture networks. A systematic set of new benchmark cases has been derived based on the GREAT cell experiments. An analysis of the constant normal load (CNL) experiment has been conducted using micro- and macroscopic approaches, based on the Freiberg experiment. The GREAT cell experiments provided a database for evaluating the mechanical and hydro-mechanical responses of various rock samples (resin, greywacke, gneis) in triaxial tests with a rotational stress field. Fracture permeability was determined as a function of normal stresses in the rotational stress field. The KICT experiments were used to investigate thermally induced shear slip and dilation processes. The SAFENET Task contributed to the Open Science concept in DECOVALEX by providing a freely accessible Jupyter notebooks for selected benchmark exercises.

AB - The paper presents the key findings of Task G SAFENET of the DECOVALEX 2023 project “Safety Assessment of Fluid Flow, Shear, Thermal and Reaction Processes within Crystalline Rock Fracture NETworks”. It utilizes a systematic and experimental approach to numerically simulate mechanical (M), hydro-mechanical (HM), and thermo-mechanical (TM) fracture processes in brittle rocks. The Task team introduced, applied, and compared a wide range of numerical methods, including both continuum and discontinuum methods, for simulating related fracture processes. Task G is based on three key experiments: the Freiberg, GREAT cell, and KICT experiments, which analyze M, HM, and TM processes respectively. Classic HM and THM benchmark exercises serve as a common basis by using analytical solutions for a plane line discontinuity in a poro-elastic medium (Sneddon and Lowengrub, 1969) and a point heat source in a thermo-poro-elastic medium (Booker and Savvidou, 1985), (Chaudhry et al., 2019). These solutions also serve as a reference for rough fractures and simple fracture networks. A systematic set of new benchmark cases has been derived based on the GREAT cell experiments. An analysis of the constant normal load (CNL) experiment has been conducted using micro- and macroscopic approaches, based on the Freiberg experiment. The GREAT cell experiments provided a database for evaluating the mechanical and hydro-mechanical responses of various rock samples (resin, greywacke, gneis) in triaxial tests with a rotational stress field. Fracture permeability was determined as a function of normal stresses in the rotational stress field. The KICT experiments were used to investigate thermally induced shear slip and dilation processes. The SAFENET Task contributed to the Open Science concept in DECOVALEX by providing a freely accessible Jupyter notebooks for selected benchmark exercises.

U2 - 10.1016/j.gete.2024.100616

DO - 10.1016/j.gete.2024.100616

M3 - Article

VL - 41.2025

JO - Geomechanics for energy and the environment

JF - Geomechanics for energy and the environment

SN - 2352-3808

IS - March

M1 - 100616

ER -

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