Continuum Modeling of Secondary Rheology in Dense Granular Materials

Henann, David L.; Kamrin, Ken

doi:10.1103/physrevlett.113.178001

Cited by 77 publications

(56 citation statements)

References 33 publications

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“…This spatial dependence demonstrates that local rheology may be not sufficient to describe strong non-parallel flows such as the present flow around a cylinder. While such spatial variations of µ have been recently predicted by non-local modeling in intruder geometry [10], the finite level of dilatancy D of stationary flows has not been reported yet theoretically or numerically. The present finding may thus put further constraints on the formulation of continuum models by opening up novel challenge in modeling and understanding non-parallel compressible granular flows using compressible non-local rheology.…”

Section: Discussionmentioning

confidence: 99%

“…The present finding may thus put further constraints on the formulation of continuum models by opening up novel challenge in modeling and understanding non-parallel compressible granular flows using compressible non-local rheology. Experimentally, checking for non-local rheology is challenging as the computation of Laplacian terms -at the core of these non-local models [8,10] -is hampered by finite resolution and large fluctuations.…”

Section: Discussionmentioning

confidence: 99%

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Local rheological measurements in the granular flow around an intruder

et al. 2016

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The rheological properties of granular matter within a two-dimensional flow around a moving disk is investigated experimentally. Using a combination of photoelastic and standard tessellation techniques, the strain and stress tensors are estimated at the grain scale in the time-averaged flow field around a large disk pulled at constant velocity in an assembly of smaller disks. On the one hand, one observes inhomogeneous shear rate and strongly localized shear stress and pressure fields. On the other hand, a significant dilation rate, which has the same magnitude as the shear strain rate, is reported. Significant deviations are observed with local rheology that justify the need of searching for a non-local rheology.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Local rheological measurements in the granular flow around an intruder

et al. 2016

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“…It bears noting that we have observed no evidence of numerical instabilities or spurious oscillation patterns in our calculations. Since the model has shown promise in predicting granular flows [14,16], we expect that the ability to robustly solve these equations will be of use to researchers working in the field, and hence, we have made all Abaqus UEL subroutines 27 and input files available as supporting information. One possible limitation of the approach is that it does not smoothly transition to the local case.…”

Section: Resultsmentioning

confidence: 99%

“…However, the mathematical system of equations is non-standard, and solving these equations in arbitrary flow configurations presents a new challenge. The purpose of this paper is to report on our finite-element-based approach to solving boundary-value problems with the nonlocal granular rheology, which we have utilized in our past work [14,16], and show that our approach is robust. Several specific questions that arise in formulating a finite-element implementation are…”

Section: Introductionmentioning

confidence: 99%

A finite element implementation of the nonlocal granular rheology

Henann¹,

Kamrin²

2016

Numerical Meth Engineering

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SUMMARYInhomogeneous flows involving dense particulate media display clear size effects, in which the particle length scale has an important effect on flow fields. Hence, nonlocal constitutive relations must be used in order to predict these flows. Recently, a class of nonlocal fluidity models have been developed for emulsions and subsequently adapted to granular materials. These models have successfully provided a quantitative description of experimental flows in many different flow configurations. In this work, we present a finiteelement-based numerical approach for solving the nonlocal constitutive equations for granular materials, which involve an additional, non-standard nodal degree-of-freedom -the granular fluidity, which is a scalar state parameter describing the susceptibility of a granular element to flow. Our implementation is applied to three canonical inhomogeneous flow configurations: (i) linear shear with gravity, (ii) annular shear flow without gravity, and (iii) annular shear flow with gravity. We verify our implementation, demonstrate convergence, and show that our results are mesh-independent.

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“…Note that in spite of resemblances, this phenomenon is a priori different from another fluidization process occurring when a granular packing is placed in contact with a fluidized shear band [38,39]. In the last case, theoretical analysis and numerical simulations show that the induced creeping process comes from a non-local stress relaxation, from the flowing part to the material bulk [40][41][42][43]. The generality of the scenario, mixing two generic features of glassy system make it suitable to be tested experimentally on many other practical situation like colloidal glasses, pastes, clays or even glass-former molecular systems, which actually may turn out to be of practical importance to assess the stability and reliability of structures strained externally in their environment over very long time scales.…”

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confidence: 99%

Mechanical fluctuations suppress the threshold of soft-glassy solids: The secular drift scenario

et al. 2015

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We propose a dynamical mechanism leading to the fluidization by external mechanical fluctuations of soft-glassy amorphous material driven below the yield-stress. The model is based on the combination of memory effect and non-linearity, leading to an accumulation of tiny effects over a long-term. We test this scenario on a granular packing driven mechanically below the Coulomb threshold. We bring evidences for an effective viscous response directly related to small stress modulations in agreement with the theoretical prediction of a generic secular drift. We finally propose to extend this result more generally, to a large class of glassy systems.PACS numbers: 81.40. Lm, 83.80.Fg Numerous amorphous materials such as concentrated suspensions, colloidal glasses, foams or granular materials share common global features in their mechanical response to shear [1,2]. They are characterized by a yield stress below which the material appears as a solid [3,4]. As this behaviour is shared by so many different materials, several conceptual and theoretical frameworks emerged recently [5][6][7][8][9][10] to provide a quantitative basis for the phenomenology of soft glassy rheology (SGR) above and beyond the yield stress. Even though many parallel approaches exist, sometimes at different level of description, they all share either explicitly or implicitly, the underlying idea that mesoscopic collective processes triggered by thermal or mechanical activation, contribute to the material fluidity. The direct visualization of local plastic events and the associated complex avalanching dynamics is supported by many experimental [11][12][13][14] or numerical [15][16][17] studies. In the "solid phase" corresponding to a strong dynamical arrest, soft-glassy systems display ageing properties manifesting in a slow creep relaxation process [18][19][20][21]. Ageing properties stem from a remaining thermal activation providing the possibility to cross enthalpic or entropic barriers and progressively set the system into deeper local minima where mechanical solidity is reinforced. The existence of external mechanical noise was also proposed as a substitute for thermal activation. In this sense, the behaviour of these amorphous soft glassy solids is very close phenomenologically to molecular glass-formers obtained by thermal quenching [22]. Yet, the fact that such mechanical noise truly acts as an effective temperature is presently debated [23] and indeed, deep differences in the way thermal noise and mechanical fluctuations act in amorphous systems has been recently pointed out [24].

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Continuum Modeling of Secondary Rheology in Dense Granular Materials

Cited by 77 publications

References 33 publications

Local rheological measurements in the granular flow around an intruder

Local rheological measurements in the granular flow around an intruder

A finite element implementation of the nonlocal granular rheology

Mechanical fluctuations suppress the threshold of soft-glassy solids: The secular drift scenario

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