Microstructural analysis of sheared polydisperse polyhedral grains

Granular materials often present correlations between particle size and shape due to their geological formation and mechanisms of weathering and fragmentation. It is known that particle shape strongly affects shear strength. However, the effects of shape can be modified by the role the particle plays in a sample given its size. We explore the steady shear strength of samples composed of particles presenting size‐shape correlations and we focus on the case of particle elongation in two opposite scenarios: (A) large elongated grains with finer circular grains and (B) large circular grains with elongated finer grains. By means of numerical simulations, we probe the shear strength of samples of varying particle size span from mono to highly polydisperse and particle aspect ratios varying between 1 and 5. We find that the two correlations tested strongly impact the shear strength as particle size span evolves. Microstructural analyzes allow us to identify how each correlation affects connectivity and anisotropies linked to the orientation of the particles and load transmission. Decompositions of the stress tensor let us identify the sources of the different mechanical behavior in each correlation and determine the contributions of each particle shape to macroscopic shear strength. This study proves that common small‐scaling methods based on truncated or parallel particle size distributions can incur in under/over‐estimations of shear strength if particle shapes are not considered in the scaling process.

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“…Since the role of each particle shape in a given psd can largely vary for a given granular material. We can decompose the total shear strength

q/p

in order to assess the contributions of each shape class on the shear strength, as 55

\begin{equation} q/p = \frac{1}{p} \sum _{i=1}^{N_{sc}} q_i, \end{equation}

…”

Section: Micromechanical Contributions To Strengthmentioning

confidence: 99%

Effects of particle size‐shape correlations on steady shear strength of granular materials: The case of particle elongation

Carrasco

Cantor

Ovalle

2022

Num Anal Meth Geomechanics

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“…This is not only due to the development of advanced experimental devices or the increasing computational power and numerical techniques, but because many fundamental behaviors have already been described for assemblies of rigid grains [10,11]. Among these behaviors, we find the transition to jamming [12][13][14][15][16], the force transmission [17][18][19][20], or the effects induced by particle geometry [21][22][23][24][25][26][27][28][29][30], to name a few.…”

Section: Introductionmentioning

confidence: 95%

Micromechanical description of the compaction of soft pentagon assemblies

et al. 2021

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We analyze the isotropic compaction of assemblies composed of soft pentagons interacting through classical Coulomb friction via numerical simulations. The effect of the initial particle shape is discussed by comparing packings of pentagons with packings of soft circular particles. We characterize the evolution of the packing fraction, the elastic modulus, and the microstructure (particle rearrangement, connectivity, contact force, and particle stress distributions) as a function of the applied stresses. Both systems behave similarly: the packing fraction increases and tends asymptotically to a maximum value φ max , where the bulk modulus diverges. At the microscopic scale we show that particle rearrangements occur even beyond the jammed state, the mean coordination increases as a square root of the packing fraction, and the force and stress distributions become more homogeneous as the packing fraction increases. Soft pentagons experience larger particle rearrangements than circular particles, and such behavior decreases proportionally to the friction. Interestingly, the friction between particles also contributes to a better homogenization of the contact force network in both systems. From the expression of the granular stress tensor we develop a model that describes the compaction behavior as a function of the applied pressure, the Young modulus, and the initial shape of the particles. This model, settled on the joint evolution of the particle connectivity and the contact stress, provides outstanding predictions from the jamming point up to very high densities.

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“…This is not only due to the development of advanced experimental devices or the increasing computational power and numerical technics, but because many fundamental behaviors have already been described for assemblies of rigid grains [10,11]. Among these behaviors, we find the transition to jamming [12][13][14][15][16], the force transmission [17][18][19][20], or the effects induced by particle geometry [21][22][23][24][25][26][27][28][29][30],…”

Section: Introductionmentioning

confidence: 90%

Micromechanical description of the compaction of soft pentagon assemblies

Cárdenas-Barrantes,

Cantor,

Barés

et al. 2020

Preprint

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We analyze the isotropic compaction of assemblies composed of soft pentagons interacting through classical Coulomb friction via numerical simulations. The effect of the initial particle shape is discussed by comparing packings of pentagons with packings of soft circular particles. We characterize the evolution of the packing fraction, the elastic modulus, and the microstructure (particle rearrangement, connectivity, contact force and particle stress distributions) as a function of the applied stresses. Both systems behave similarly; the packing fraction increases and tends asymptotically to a maximum value φmax, where the bulk modulus diverges. At the microscopic scale we show that particle rearrangements occur even beyond the jammed state, the mean coordination increases as a square root of the packing fraction and, the force and stress distributions become more homogeneous as the packing fraction increases. Soft pentagons present larger particle rearrangements than circular ones, and such behavior decreases proportionally to the friction. Interestingly, the friction between particles also contributes to a better homogenization of the contact force network in both systems. From the expression of the granular stress tensor, we develop a model that describes the compaction behavior as a function of the applied pressure, the Young modulus and the initial shape of the particles. This model, settled on the joint evolution of the particle connectivity and the contact stress, provides outstanding predictions from the jamming point up to very high densities.

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Microstructural analysis of sheared polydisperse polyhedral grains

Cited by 24 publications

References 56 publications

Effects of particle size‐shape correlations on steady shear strength of granular materials: The case of particle elongation

Effects of particle size‐shape correlations on steady shear strength of granular materials: The case of particle elongation

Micromechanical description of the compaction of soft pentagon assemblies

Micromechanical description of the compaction of soft pentagon assemblies

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