Effects of loading types on micro-fracturing and the inherent acoustic emissions in isotropic rocks: a numerical study

Alberto  Varela-Valdez; Gilles Pijaudier-Cabot; Moises Hinojosa-Rivera; Victor I.  Germán Flores

doi:10.31349/RevMexFis.72.021002

Authors

A. Varela-Valdez Departamento de Minería, Instituto Tecnológico Superior Zona Occidente https://orcid.org/0000-0002-1682-1642
G. Pijaudier-Cabot Université de Pau et de Pays de l'Adour https://orcid.org/0000-0002-3464-3229
M. Hinojosa-Rivera Universidad Autónoma de Nuevo León
V. I. German Flores Universidad Autónoma de Nuevo León

DOI:

https://doi.org/10.31349/RevMexFis.72.021002

Keywords:

micro-fracturing, discrete element method, acoustic emission, Gutenberg-Richter law, rock mechanics

Abstract

This study investigates the micro-fracturing of a Statistical Element Volume (SEV), and the emergent acoustic emissions under three loading conditions: simple tension, direct shear, and uniaxial compression. Employing the Discrete Element Method (DEM), the spring-beam bond model, and an elliptic fracture criterion, the SEV created simulates quasi-brittle materials, akin to rocks, featuring key properties like Young’s modulus, shear modulus, Poisson’s ratio, and ratios between maximum compression /tensile strengths around 10. Our analysis reveals a fracture behavior in bond energy (and AE) following a power law behavior analogous to Gutenberg-Richter law. In tension and shear, the power laws are similar. It is under uniaxial compression that a difference is observed. The statistics of bond energy displays two regimes corresponding to two exponents b in the Gutenberg Richter law. These two regimes can be distinguished by considering the state of stress upon failure. In the post peak regime, which is also a dilatant regime of deformation, high energy events are related to compression-shear loads. Such events are very seldom in tension, shear or in the pre-peak regime under uniaxial compression.

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Effects of loading types on micro-fracturing and the inherent acoustic emissions in isotropic rocks: a numerical study

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