Bonded-cell model for particle fracture
Author(s)
Nguyen, Duc-Hanh; Azema, Emilien; Sornay, Philippe; Radjai, Farhang
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Particle degradation and fracture play an important role in natural granular flows and in many applications of granular materials. We analyze the fracture properties of two-dimensional disklike particles modeled as aggregates of rigid cells bonded along their sides by a cohesive Mohr-Coulomb law and simulated by the contact dynamics method. We show that the compressive strength scales with tensile strength between cells but depends also on the friction coefficient and a parameter describing cell shape distribution. The statistical scatter of compressive strength is well described by the Weibull distribution function with a shape parameter varying from 6 to 10 depending on cell shape distribution. We show that this distribution may be understood in terms of percolating critical intercellular contacts. We propose a random-walk model of critical contacts that leads to particle size dependence of the compressive strength in good agreement with our simulation data.
Date issued
2015-02Department
MIT Energy InitiativeJournal
Physical Review E
Publisher
American Physical Society
Citation
Nguyen, Duc-Hanh, Emilien Azéma, Philippe Sornay, and Farhang Radjai. “Bonded-Cell Model for Particle Fracture.” Phys. Rev. E 91, no. 2 (February 2015) © 2015 American Physical Society
Version: Final published version
ISSN
1539-3755
1550-2376