Multiscale plasticity of geomaterials predicted via constrained optimization‐based granular micromechanics

Bryant, Eric C.; Bennett, Kane C.; Miller, Nathan; Misra, Anil

doi:10.1002/nag.3320

Cited by 7 publications

(2 citation statements)

References 88 publications

(178 reference statements)

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“…Because our Automated segmentation method is affected to a lesser extent by the constraints of geometry and size, this method can easily be expanded for changes in geometry: larger fields of view, and progressing to 3D microstructural models, which is part of our current and ongoing work. Finally, we note that the methods and results provided here are important to inform our present granular homogenization and data-driven modeling research [33][34].…”

Section: Discussionmentioning

confidence: 99%

Multiscale numerical investigation of ratchet growth damage effects in PBX 9502

Hagengruber,

Bennett,

Boyce

et al. 2023

Propellants Explo Pyrotec

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This paper presents results of numerical experiments conducted on the high explosive PBX 9502 to investigate how recently observed grain‐scale damage mechanisms of ratchet growth [1] affect uniaxial compression measurements. Simulations are multiscale in the sense of directly resolving grains, pores, cracks, and grain‐interfaces based upon scanning electron microscope (SEM) images of damaged and undamaged samples. The combined finite‐discrete element method (FDEM) is utilized to resolve both grain‐scale microfracture and elastoplastic deformation of solid grains. Pristine (undamaged) and damaged microstructures are compared in simulation of unconfined compression tests of the same material from the literature. The simulation results show the observed microscale mechanisms of damage, specifically microfracture predominantly around and sometimes through grains and crack‐associated pore growth, can well‐explain the effective degradation of strength and stiffness observed in the laboratory measurements.

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Section: Discussionmentioning

confidence: 99%

Multiscale numerical investigation of ratchet growth damage effects in PBX 9502

Hagengruber,

Bennett,

Boyce

et al. 2023

Propellants Explo Pyrotec

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“…Geomechanics models for elastoplasticty and damage have of course also been a topic of much development. Pressure dependency of strength has long been well-understood, 21,22 but continues to be developed, for example, for multiscale modeling, 23 coupling to damage, [24][25][26] anisotropy [27][28][29] and for various other needs. 30 Similarly, computational models inclusive of compactive yielding have been well elucidated, 31 but there remain various topics of active development, such as coupling to damage, [32][33][34] thermodynamic-consistency at large deformation, 35 and dynamic applications.…”

Section: Introductionmentioning

confidence: 99%

An integrated EOS, pore‐crush, strength and damage model framework for near‐field ground‐shock

Bennett,

Stahl,

Canfield

et al. 2024

Num Anal Meth Geomechanics

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An integrated Equation of State (EOS) and strength/pore‐crush/damage model framework is provided for modeling near to source (near‐field) ground‐shock response, where large deformations and pressures necessitate coupling EOS with pressure‐dependent plastic yield and damage. Nonlinear pressure‐dependence of strength up to high‐pressures is combined with a Modified Cam‐Clay‐like cap‐plasticity model in a way to allow degradation of strength from pore‐crush damage, what we call the “Yp‐Cap” model. Nonlinear hardening under compaction allows modeling the crush‐out of pores in combination with a fully saturated EOS, that is, for modeling partially saturated ground‐shock response, where air‐filled voids crush. Attention is given to algorithmic clarity and efficiency of the provided model, and the model is employed in example numerical simulations, including finite element simulations of underground explosions to exemplify its robustness and utility.

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A new block-based approach for the analysis of damage in masonries undergoing large deformations

Tran

Barchiesi

2022

Continuum Mech. Thermodyn.

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Multiscale plasticity of geomaterials predicted via constrained optimization‐based granular micromechanics

Cited by 7 publications

References 88 publications

Multiscale numerical investigation of ratchet growth damage effects in PBX 9502

Multiscale numerical investigation of ratchet growth damage effects in PBX 9502

An integrated EOS, pore‐crush, strength and damage model framework for near‐field ground‐shock

A new block-based approach for the analysis of damage in masonries undergoing large deformations

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