Micromechanical controls on the brittle-plastic transition in rocks

Liu, Dong; Brantut, Nicolas

doi:10.1093/gji/ggad065

Cited by 4 publications

(1 citation statement)

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“…Appendix A. Discretization using the Gauss-Chebyshev quadrature Gauss-Chebyshev quadrature combined with the Barycentric interpolation techniques provide an efficient way to solve elastic boundary integral solutions arising in fracture problems (Viesca and Garagash, 2017;Liu and Brantut, 2022). It has been recently applied to semi-infinite (Garagash, 2019) and finite hydraulic fracture propagation problems (Liu et al, 2019;Kanin et al, 2021;Möri and Lecampion, 2021;Pereira and Lecampion, 2021), illustrating a spectral accuracy and efficiency in large time span semi-analytical investigation.…”

Section: Credit Authorship Contribution Statementmentioning

confidence: 99%

Effects of velocity-dependent apparent toughness on the pre- and post-shut-in growth of a hydraulic fracture

Liu

2023

Computers and Geotechnics

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Section: Credit Authorship Contribution Statementmentioning

confidence: 99%

Effects of velocity-dependent apparent toughness on the pre- and post-shut-in growth of a hydraulic fracture

Liu

2023

Computers and Geotechnics

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Early-Time Shut-In for Plane-Strain Hydraulic Fractures

Liu

2023

Rock Mech Rock Eng

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One investigates the post-shut-in growth of a plane-strain hydraulic fracture in an impermeable medium while accounting for the possible presence of a fluid lag. After the stop of fluid injection, the fracture may present three distinct propagation patterns: an immediate arrest, a temporary arrest with delayed propagation, and a continuous fracture growth. These three patterns are all followed by a final fracture arrest yet the fracture behaviour prior to that results from the interplay between the dimensionless toughness $$\mathcal {K}_m$$ K m , the shut-in time $$t_s/t_{om}$$ t s / t om , and the propagation time $$t/t_s$$ t / t s . $$\mathcal {K}_m$$ K m characterizes the energy dissipation ratio between fracture surface creation and viscous fluid flow under constant rate injection. $$t_s$$ t s and $$t_{om}$$ t om represent respectively the timescale of shut-in and the coalescence of the fluid and fracture fronts. The immediate arrest occurs when the fracture toughness dominates the fracture growth at the stop of injection ($$\mathcal {K}_m \gtrapprox 4.3$$ K m ⪆ 4.3 ). It may also occur upon an early shut-in at low dimensionless toughness associated with an overshoot of fracture extension and a significant fluid lag. For intermediate values of $$\mathcal {K}_m$$ K m and $$t_s/t_{om}$$ t s / t om , the fracture may experience a temporary arrest followed by a restart of fracture propagation. The period of the temporary arrest becomes shorter with higher dimensionless toughness and later shut-in until it drops to zero. The fracture behaviour after shut-in then transitions from temporary arrest to continuous propagation. These propagation patterns result in different evolution of fracture dimensions which possibly explains the various emplacement scaling relations reported in magmatic dikes.

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