Up, down, and round again: The circulating flow dynamics of flux-driven fractures

Chalk, C. M.; Kavanagh, J. L.

doi:10.1063/5.0187217

Physics of Fluids

2024

DOI: 10.1063/5.0187217

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Up, down, and round again: The circulating flow dynamics of flux-driven fractures

C. M. Chalk,

J. L. Kavanagh

Abstract: Fluid-filled fracture propagation is a complex problem that is ubiquitous in geosciences, from controlling magma propagation beneath volcanoes to water transport in glaciers. Using scaled analog experiments, we characterized the internal flow inside a propagating flux-driven fracture and determined the relationship between flow and fracture evolution. Different flow conditions were created by varying the viscosity and flux (Q) of a Newtonian fluid injected into an elastic solid. Using particle image velocimetr… Show more

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Cited by 2 publications

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Erratum: “Up, down, and round again: The circulating flow dynamics of flux-driven fractures” [Phys. Fluids 36, 036622 (2024)]

Chalk,

Kavanagh

2024

Physics of Fluids

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Erratum: “Up, down, and round again: The circulating flow dynamics of flux-driven fractures” [Phys. Fluids 36, 036622 (2024)]

Chalk,

Kavanagh

2024

Physics of Fluids

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Evolution of fracture process zone and variation of crack propagation velocity in sandstone

Qiao,

Zhang,

Jiang

et al. 2024

Physics of Fluids

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To solve the safe containment and recovery efficiencies of gas in rock masses, a study on fracture process zone (FPZ) and crack propagation is conducted. By using digital image correlation technology, the displacement of three-point bending specimens was measured. By analyzing the distributions of displacement at different loading stages, a specific region between the pre-crack tip and the loading point was divided into three zones: the intact zone, the crack propagation zone, and the FPZ. The length and the migration velocity of FPZ were determined, and the crack propagation velocity was also measured. The microstructures in FPZ were investigated through optical microscopy, x-ray diffraction analysis, and x-ray photoelectron spectroscopy. The results show that (1) FPZ length slightly varies during crack propagation and the FPZ is fully formed at the peak load; (2) the average value of the bond energy (446.7 eV) in the grains is greater than that (296.7 eV) in the matrix, thus the microdamage appears in the matrix around grain boundaries in FPZ; (3) the mean FPZ length varies from 4.09 to 8.42 mm for all tested specimens during crack propagation; (4) the propagation of the crack and the migration of FPZ proceed simultaneously in the loading process, and both velocities of crack propagation and FPZ migration are almost the same and with the same trend; (5) the peak velocity of crack propagation appears after the peak load, and the crack propagation progress was intermittent due to fracture energy accumulation, fracture energy release, and FPZ's shielding effect.

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Up, down, and round again: The circulating flow dynamics of flux-driven fractures

Cited by 2 publications

References 70 publications

Erratum: “Up, down, and round again: The circulating flow dynamics of flux-driven fractures” [Phys. Fluids 36, 036622 (2024)]

Erratum: “Up, down, and round again: The circulating flow dynamics of flux-driven fractures” [Phys. Fluids 36, 036622 (2024)]

Evolution of fracture process zone and variation of crack propagation velocity in sandstone

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