Micro-macro correlations and anisotropy in granular assemblies under uniaxial loading and unloading

Imole, Olukayode Isaiah; Wojtkowski, Mateusz; Magnanimo, Vanessa; Luding, Stefan

doi:10.1103/physreve.89.042210

Cited by 38 publications

(16 citation statements)

References 54 publications

(116 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Particle rotations start to contribute as µ increases and become dominant for larger values of local friction. This leads to the saturation range which has been also obtained in bidimensional [11,43] and threedimensional simulations [15,44]. This clearly demonstrate that 2D simulations are able to reproduce important macroscopic properties, such as macroscopic friction, exhibited in 3D packings.…”

Section: B Mohr Bulk Frictionsupporting

confidence: 70%

Contact angle entropy and macroscopic friction in noncohesive two-dimensional granular packings

et al. 2017

View full text Add to dashboard Cite

We study the relationship between the granular contact angle distribution and local particle friction on the macroscopic friction and bulk modulus in noncohesive disk packings. Molecular dynamics in two dimensions are used to simulate uniaxial loading-unloading cycles imposed on the granular packings. While macroscopic Mohr friction depends on the granular pack geometric details, it reaches a stationary limit after a finite number of loading-unloading cycles that render well-defined values for bulk modulus, grain coordination, porosity, and friction. For random packings and for all polydispersities analyzed, we found that as interparticle friction increases, the bulk modulus for the limit cycle decreases linearly, while the mean coordination number is reduced and the porosity increased, also as approximately linear functions. On the other hand, the macroscopic Mohr friction increases in a monotonous trend with interparticle friction. The latter result is compared to a theoretical model that assumes the existence of sliding planes corresponding to definite Mohr-friction values. The simulation results for macroscopic friction are well described by the theoretical model that incorporates the local neighbor angle distribution that can be quantified through the contact angle entropy. As local friction is increased, the limit entropy of the neighbor angle distribution is reduced, thus introducing the geometric component to granular friction. Surprisingly, once the limit cycle is reached, the Mohr friction seems to be insensitive to polydispersity as has been recently reported.

show abstract

Section: B Mohr Bulk Frictionsupporting

confidence: 70%

Contact angle entropy and macroscopic friction in noncohesive two-dimensional granular packings

et al. 2017

View full text Add to dashboard Cite

show abstract

“…Recent works showed already that, along with the classical macroscopic properties (stress and volume fraction), the structural anisotropy is an important [41,45,46,[91][92][93][94] state-variable for granular materials, as quantified by the fabric tensor [43,68] that characterizes, on average, the geometric arrangement of the particles, the contacts and their network, i.e. the microstructure of the particle packing.…”

Section: Approach Of This Studymentioning

confidence: 99%

“…Around the jamming transition, these systems display considerable inhomogeneity, such as reflected by over-population of weak/soft/slow mechanical oscillation modes [11], forcenetworks [10,30,31], diverging correlation lengths and relaxation time-scales [9,13,22,[32][33][34][35], and some universal scaling behaviors [36,37]. Related to jamming, but at all densities, other phenomena occur, like shearstrain localization [12,16,[38][39][40], anisotropic evolution of structure and stress [7,9,11,13,30,31,[38][39][40][41][42][43][44][45][46], and force chain inhomogeneity [7,19,28]. To gain a better understanding of the jamming transition concept, one needs to consider both the structure (positions and contacts) and contact forces.…”

Section: Introductionmentioning

confidence: 99%

Memory of jamming–multiscale models for soft and granular matter

Kumar¹,

Luding²

2016

Granular Matter

Self Cite

105

149

View full text Add to dashboard Cite

Soft, disordered, micro-structured materials are ubiquitous in nature and industry, and are different from ordinary fluids or solids, with unusual, interesting static and flow properties. The transition from fluid to solid-at the socalled jamming density-features a multitude of complex mechanisms, but there is no unified theoretical framework that explains them all. In this study, a simple yet quantitative and predictive model is presented, which allows for a changing jamming density, encompassing the memory of the deformation history and explaining a multitude of phenomena at and around jamming. The jamming density, now introduced as a new state-variable, changes due to the deformation history and relates the system's macroscopic response to its micro-structure. The packing efficiency can increase logarithmically slow under gentle repeated (isotropic) compression, leading to an increase of the jamming density. In contrast, shear deformations cause anisotropy, changing the packing efficiency exponentially fast with either dilatancy or compactancy as result. The memory of the system near jamming can be explained by a micro-statistical model that involves a multiscale, fractal energy landscape and links the microscopic particle picture to the macroscopic continuum description, providing a unified explanation for the qualitatively different flow-behavior for different deformation modes. To complement our work, a recipe to extract the history-dependent jamming density from experimentally accessible data is proposed, and alternative state-variables This article is part of the Topical Collection on Micro origins for macro behavior of granular matter. are compared. The proposed simple macroscopic constitutive model is calibrated from particles simulation data, with the variable jamming density-resembling the memory of microstructure-as essential novel ingredient. This approach can help understanding predicting and mitigating failure of structures or geophysical hazards, and will bring forward industrial process design and optimization, and help solving scientific challenges in fundamental research.

show abstract

“…The deviatoric stress ratio, μ τ = p, is the effective macroscopic friction. The volumetric fabric F 3 v represents the contact number density, while the deviatoric fabric F dev quantifies the anisotropy of the contact network (as studied in detail in [53]).…”

Section: Isotropic and Deviatoric Partsmentioning

confidence: 99%

“…F F 2 1 tends to positive values for larger p*, further establishing the difference between structure and stress tensors. However, in order to have a clear picture for the fabric tensor, the strong and weak subnetworks should be studied separately, since only the strong subnetwork carries almost all of the fabric anisotropy [53,69]. Along with a non-zero σ 2 eigenvalue we do expect other aspects to show up, like the non-collinearity of the stress/strain/fabric eigensystems, related to induced anisotropy.…”

Section: Shape Factormentioning

confidence: 99%

The role of gravity or pressure and contact stiffness in granular rheology

et al. 2015

Self Cite

View full text Add to dashboard Cite

The steady-state shear rheology of granular materials is investigated in slow quasistatic and inertial flows. The effect of gravity (thus the local pressure) and the often-neglected contact stiffness are the focus of this study. A series of particle simulations are performed on a weakly frictional granular assembly in a split-bottom geometry considering various magnitudes of gravity and contact stiffnesses. While traditionally the inertial number, i.e., the ratio of stress to strain-rate time scales, is used to describe the flow rheology, we report that a second dimensionless number, the ratio of softness and stress time scales, must also be included to characterize the bulk flow behavior. For slow, quasistatic flows, the density increases while the effective (macroscopic) friction decreases with increase in either particle softness or local pressure. This trend is added to the μ I ( )rheology and can be traced back to the anisotropy in the contact network, displaying a linear correlation between the effective friction coefficient and deviatoric fabric in the steady state. When the external rotation rate is increased towards the inertial regime, for a given gravity field and contact stiffness, the effective friction increases faster than linearly with the deviatoric fabric.

show abstract

Micro-macro correlations and anisotropy in granular assemblies under uniaxial loading and unloading

Cited by 38 publications

References 54 publications

Contact angle entropy and macroscopic friction in noncohesive two-dimensional granular packings

Contact angle entropy and macroscopic friction in noncohesive two-dimensional granular packings

Memory of jamming–multiscale models for soft and granular matter

The role of gravity or pressure and contact stiffness in granular rheology

Contact Info

Product

Resources

About