Brittle-ductile failure transition in geomaterials modeled by a modified phase-field method with a varying damage-driving energy coefficient

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Brittle-ductile failure transition in geomaterials modeled by a modified phase-field method with a varying damage-driving energy coefficient. / You, Tao; Waisman, Haim; Zhu, Qizhi.
in: International journal of plasticity, Jahrgang 136.2021, Nr. January, 102836, 01.2021.

Publikationen: Beitrag in FachzeitschriftArtikelForschung(peer-reviewed)

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@article{903f1258764d42ab80b8c6102f01282c,
title = "Brittle-ductile failure transition in geomaterials modeled by a modified phase-field method with a varying damage-driving energy coefficient",
abstract = "With elevated confining pressure and low temperatures, geomaterials may exhibit brittle-to-ductile failure transition due to increased cataclastic flow. In this work, we propose a modified phase-field damage model to capture this transition, wherein a portion χf of the plastic work that contributes to the fracture driving force, is assumed. In particular, we propose to compute χf based on a specific normalized stress parameter based on Byerlee's rule, which ranges from brittle tension fracture to cataclastic flow. In the former case, all the stored plastic free energy is assumed to contribute to fracture. However, in all other cases, the brittle fracture process at the macroscale is gradually suppressed with the increase of pressure, rendering a smaller value of χf. The proposed model includes eight material parameters, all of which can be calibrated from standard laboratory tests, i.e., conventional triaxial compressive experiments. To validate the performance of the proposed model, three pre-cracked specimens are constructed under plane strain conditions. Numerical simulations show that the predicted failure patterns agree with the experimental testing, which highlights the predictive capability of the model to capture brittle and ductile failure mechanisms. In addition, the proposed model can describe the brittle-ductile failure transition behavior in the homogeneous case and can predict the realistic failure process at the structural level.",
keywords = "Brittle-ductile transition, Byerlee's rule, Crack propagation, Damage-plasticity coupling, Geomaterials, Phase-field method, Shear band",
author = "Tao You and Haim Waisman and Qizhi Zhu",
note = "Publisher Copyright: {\textcopyright} 2020 Elsevier Ltd.",
year = "2021",
month = jan,
doi = "10.1016/j.ijplas.2020.102836",
language = "English",
volume = "136.2021",
journal = "International journal of plasticity",
issn = "0749-6419",
publisher = "Elsevier",
number = "January",

}

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TY - JOUR

T1 - Brittle-ductile failure transition in geomaterials modeled by a modified phase-field method with a varying damage-driving energy coefficient

AU - You, Tao

AU - Waisman, Haim

AU - Zhu, Qizhi

N1 - Publisher Copyright: © 2020 Elsevier Ltd.

PY - 2021/1

Y1 - 2021/1

N2 - With elevated confining pressure and low temperatures, geomaterials may exhibit brittle-to-ductile failure transition due to increased cataclastic flow. In this work, we propose a modified phase-field damage model to capture this transition, wherein a portion χf of the plastic work that contributes to the fracture driving force, is assumed. In particular, we propose to compute χf based on a specific normalized stress parameter based on Byerlee's rule, which ranges from brittle tension fracture to cataclastic flow. In the former case, all the stored plastic free energy is assumed to contribute to fracture. However, in all other cases, the brittle fracture process at the macroscale is gradually suppressed with the increase of pressure, rendering a smaller value of χf. The proposed model includes eight material parameters, all of which can be calibrated from standard laboratory tests, i.e., conventional triaxial compressive experiments. To validate the performance of the proposed model, three pre-cracked specimens are constructed under plane strain conditions. Numerical simulations show that the predicted failure patterns agree with the experimental testing, which highlights the predictive capability of the model to capture brittle and ductile failure mechanisms. In addition, the proposed model can describe the brittle-ductile failure transition behavior in the homogeneous case and can predict the realistic failure process at the structural level.

AB - With elevated confining pressure and low temperatures, geomaterials may exhibit brittle-to-ductile failure transition due to increased cataclastic flow. In this work, we propose a modified phase-field damage model to capture this transition, wherein a portion χf of the plastic work that contributes to the fracture driving force, is assumed. In particular, we propose to compute χf based on a specific normalized stress parameter based on Byerlee's rule, which ranges from brittle tension fracture to cataclastic flow. In the former case, all the stored plastic free energy is assumed to contribute to fracture. However, in all other cases, the brittle fracture process at the macroscale is gradually suppressed with the increase of pressure, rendering a smaller value of χf. The proposed model includes eight material parameters, all of which can be calibrated from standard laboratory tests, i.e., conventional triaxial compressive experiments. To validate the performance of the proposed model, three pre-cracked specimens are constructed under plane strain conditions. Numerical simulations show that the predicted failure patterns agree with the experimental testing, which highlights the predictive capability of the model to capture brittle and ductile failure mechanisms. In addition, the proposed model can describe the brittle-ductile failure transition behavior in the homogeneous case and can predict the realistic failure process at the structural level.

KW - Brittle-ductile transition

KW - Byerlee's rule

KW - Crack propagation

KW - Damage-plasticity coupling

KW - Geomaterials

KW - Phase-field method

KW - Shear band

UR - http://www.scopus.com/inward/record.url?scp=85097548890&partnerID=8YFLogxK

U2 - 10.1016/j.ijplas.2020.102836

DO - 10.1016/j.ijplas.2020.102836

M3 - Article

AN - SCOPUS:85097548890

VL - 136.2021

JO - International journal of plasticity

JF - International journal of plasticity

SN - 0749-6419

IS - January

M1 - 102836

ER -