A nonlinear constitutive model for whole stress–strain behaviors of compressed rocks incorporating crack closure effect

Abstract: This paper is devoted to establishing a nonlinear constitutive model incorporating crack closure effect for capturing the whole process of rock deformation and failure behavior under compression. The model formulated in the framework of irreversible thermodynamics is based on the additive decomposition of the total strain into crack closure strain, elastic, and plastic parts. New specific criteria are proposed for the description of crack closure strain and plastic strain evolution. Notably, analytical solutio… Show more

“…Prior researches mainly focus on the room temperature conditions and take into account the influence of mesocracking evolution on the damage resistance, with appreciable success achieved in modeling hardening/weakening behaviors of quasi‐brittle rocks (Q. Z. Zhu et al., 2016; Zhao, Shao, & Zhu, 2018; Ren et al., 2023; C. X. Zhao, Liu, et al., 2023).…”

“…Among them, the temperature dependence of fundamental mechanical properties of quasi‐brittle rocks, including peak strength, plastic deformation, damage evolution, and strain hardening/softening, was typically characterized by employing empirical equations. Note that some of these models have been further modified to describe the mechanical response of geologic materials under hydro‐thermal‐mechanical (Long, 2021), thermal‐creep (Geng et al., 2018), and freeze‐thaw cyclic loading (Ren et al., 2023; Zhao et al., 2020). These macroscopic models explicitly present stress‐strain relationships and short‐ and long‐term strength criteria, which facilitate analysis of specific rock and mining engineering using finite element (Long, 2021), discrete element (Fan et al., 2021), phase field method (J. Liu, Ji, et al., 2020).…”

Micro‐Thermomechanical Modeling of Rocks With Temperature‐Dependent Friction and Damage Laws

“…Prior researches mainly focus on the room temperature conditions and take into account the influence of mesocracking evolution on the damage resistance, with appreciable success achieved in modeling hardening/weakening behaviors of quasi‐brittle rocks (Q. Z. Zhu et al., 2016; Zhao, Shao, & Zhu, 2018; Ren et al., 2023; C. X. Zhao, Liu, et al., 2023).…”

“…Among them, the temperature dependence of fundamental mechanical properties of quasi‐brittle rocks, including peak strength, plastic deformation, damage evolution, and strain hardening/softening, was typically characterized by employing empirical equations. Note that some of these models have been further modified to describe the mechanical response of geologic materials under hydro‐thermal‐mechanical (Long, 2021), thermal‐creep (Geng et al., 2018), and freeze‐thaw cyclic loading (Ren et al., 2023; Zhao et al., 2020). These macroscopic models explicitly present stress‐strain relationships and short‐ and long‐term strength criteria, which facilitate analysis of specific rock and mining engineering using finite element (Long, 2021), discrete element (Fan et al., 2021), phase field method (J. Liu, Ji, et al., 2020).…”

Micro‐Thermomechanical Modeling of Rocks With Temperature‐Dependent Friction and Damage Laws

Three-dimensional elastoplastic constitutive model for cement stone based on fractional flow rule

Elastoplastic damage behavior of quasi-brittle rocks considering crack closure evolution