Multi-scale interaction potentials (F − r) for describing fracture of brittle disordered materials like cement and concrete

Mier, J.G.M. van

doi:10.1007/s10704-007-9050-0

Cited by 34 publications

(2 citation statements)

References 84 publications

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“…Particle models represent one of many attempts to bridge the gap between the spatial scales. The PD, utilized in the present study, can be envisioned as a generalization of spring network models with dynamic effects included and can also be considered an engineering offshoot of molecular dynamics (MD) on a coarser spatial scale ("quasi-MD" [17]). The choice of the coarser spatial scale implies that the role of atoms/molecules is being taken over by "continuum" particles or quasi-particles mimicking a larger chunk of material.…”

Section: Computer Simulation Techniquementioning

confidence: 99%

A PD simulation-informed prediction of penetration depth of rigid rods through materials susceptible to microcracking

Mastilović

2022

Meccanica

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The present investigation relies upon an alternative approach to estimate the penetration depth of rigid projectiles into quasibrittle materials that utilizes simulation-informed modeling of penetration resistance. Penetration at normal incidence of a long rigid rod into massive targets, made of materials with inferior tensile strength predisposed to microcracking, is an event characterized by a high level of aleatory variability and epistemic uncertainty. This inherent stochasticity of the phenomenon is addressed by a model developed based on the particle dynamics (PD) simulations aimed to provide a key modeling ingredient -the functional dependence of the radial traction at the cavity surface on the radial velocity of the cavity expansion. The penetration depth expressions are derived for the ogive nose projectiles. The use of the power law radial traction dependence upon the expansion rate yields the penetration resistance and depth equations defined in terms of hypergeometric functions. These expressions are readily evaluated and offer a reasonably conservative estimate of the penetration depth. This model is validated by using experimental results of the penetration depth of long projectiles into Salem limestone, which is a typical example of quasibrittle materials with random microstructure well known for their pronounced experimental data scatter. This stochasticity is explored in the present paper by a sensitivity analysis of the key input parameters of the model; most notably, uniaxial tensile strength and friction coefficient.

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Section: Computer Simulation Techniquementioning

confidence: 99%

A PD simulation-informed prediction of penetration depth of rigid rods through materials susceptible to microcracking

Mastilović

2022

Meccanica

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“…Material properties must therefore be determined at a smaller scale than the above described cube compression test; nevertheless all the same constraints are met and one is never certain whether the adopted properties are true material properties. Expectations are that a linear-brittle fractue law could suffice at a small scale for quasi-brittle materials like concrete, although some mechansisms acting at micro-scale ([µm]-scale in cement and smaller) to direct to the use of softening after all [11].…”

Section: Simple Lattice Analysismentioning

confidence: 99%

Fracture of Quasi-Brittle Materials like Concrete under Compressive Loading

Mier

Meyer

Man

2008

AMR

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Fracture under compression is one of the most commonly studied properties of geomaterials like concrete and rock, in particular since these materials reach their best performance in compression. The fracture process is however rather complex due to the heterogeneous structures of said materials. Over the years fundemental studies of fracture under compression have led to a much improved insight in the details of the fracture process depending on the actual composition of the material. Fracture can be described by means of a 4-stage fracture model, which included as most important aspects pre-peak cracking, which is stable and can be arrested by stiffer and stronger elements in the material structure, and post-peak cracking [1]. The latter macroscopic cracks are basically un-stable and can only be arrested by measures at a structural scale, such as applying confining stress or by using positive geometries. The material structure cannot assist in the arrest of the large energetic cracks other than locally affecting the crack path. In the paper an overview is given of the fracture process in compression. Recently we embarked on studying compressive fracture using a simpler material structure, namely foamed hardened cement paste [2]. Stiff aggregates that are normally included in normal concrete have been left-out; instead a larger than usual quantity of large pores is brought into the material, even up to 80%. Studying fracture processes in this simpler material system ultimately allows for a better understanding of the details of the pre-peak cracking process, which is considered more important than the post-peak process since it defines strength.

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A solution to the parameter-identification conundrum: multi-scale interaction potentials

Mier

2014

Fracture Phenomena in Nature and Technology

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Softening is a structural property, not a material property. Any material will show softening, but in this paper the focus is primarily on cement and concrete, which show this property very clearly owing to their coarse heterogeneity (relative to common laboratory-scale specimen sizes). A new model approach is presented, based on pair-potentials describing the interaction between two neighbouring particles at any desired size/scale level. Because of the resemblance with a particle model an equivalent lattice can be constructed. The pair-potential is then the behavioral law of a single lattice element. This relation between force and displacement depends on the size of the considered lattice element as well as on the rotational stiffness at the nodes, which not only depends on the flexibility of the global lattice to which the element is connected but also on the flexural stiffness of the considered element itself. The potential F − r relation is a structural property that can be directly measured in physical experiments, thereby solving size effects and boundary effects.

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Multi-scale interaction potentials (F − r) for describing fracture of brittle disordered materials like cement and concrete

Cited by 34 publications

References 84 publications

A PD simulation-informed prediction of penetration depth of rigid rods through materials susceptible to microcracking

A PD simulation-informed prediction of penetration depth of rigid rods through materials susceptible to microcracking

Fracture of Quasi-Brittle Materials like Concrete under Compressive Loading

A solution to the parameter-identification conundrum: multi-scale interaction potentials

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