Granular hypoplasticity with Cosserat effects

Goddard, J. D.

doi:10.1063/1.3435403

Cited by 10 publications

(14 citation statements)

References 32 publications

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“…The original reason for this behavior becomes clear looking at Figs. 4(g) and 4(h), where the variation of the contractancy/dilatancy ratio AS/2B (during initial loading (0) and the odd reversal points (1,3,5,7,9)) is shown for the two different β A . At the beginning (0), the quantity becomes always negative due to the initial decrease of A: that is, the system always shows initial dilatancy, see path 0 − 1 in 4(e) and 4(f).…”

Section: Strain Reversalmentioning

confidence: 99%

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A local constitutive model with anisotropy for ratcheting under 2D axial-symmetric isobaric deformation

Magnanimo¹,

Luding²

2011

Granular Matter

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A local constitutive model for anisotropic granular materials is introduced and applied to isobaric (homogeneous) axial-symmetric deformation. The simplified model (in the coordinate system of the bi-axial box) involves only scalar values for hydrostatic and shear stresses, for the volumetric and shear strains as well as for the new ingredient, the anisotropy modulus.The non-linear constitutive evolution equations that relate stress and anisotropy to strain are inspired by observations from Discrete Element Method (DEM) simulations. For the sake of simplicity, parameters like the bulk and shear modulus are set to constants, while the shear stress ratio and the anisotropy evolve with different rates to their critical state limit values when shear deformations become large.When applied to isobaric deformation in the bi-axial geometry, the model shows ratcheting under cyclic loading. Fast and slow evolution of anisotropy with strain (relative to the evolution of anisotropy in stress) lead to dilatancy and contractancy, respectively. Furthermore, anisotropy acts such that it works "against" the strain/stress, e.g., a compressive strain builds up anisotropy that creates additional stress acting against further compression.

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Section: Strain Reversalmentioning

confidence: 99%

“…Only few theories, see e.g. [2,7,15,[18][19][20]22] and references therein, involve an anisotropy state variable. The influence of the micromechanics on the noncoaxiality of stress, strain and anisotropy of soils is described e.g.…”

Section: Introductionmentioning

confidence: 99%

A local constitutive model with anisotropy for ratcheting under 2D axial-symmetric isobaric deformation

Magnanimo¹,

Luding²

2011

Granular Matter

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“…Because of the small length scales, such effects are expected to be relatively weak in the molecular system, other than in liquid crystals or in experiments involving high-frequency (large k, s) response. The situation is different at larger particle scales in fields such as granular mechanics and rotational seismology [20,35,17,14], where gradient effects can be much more important. Setting aside non-linear (amplitude) effects, the non-local model of viscoelasticity (34), which is also applicable to anisotropic materials, is readily modified to incorporate couple-stress effects.…”

Section: Other Variables and Effectsmentioning

confidence: 99%

“…A recently proposed complex-variable representation [14], with complex stress T + ıM and complex velocity v + ıx giving a single balance for linear and angular momentum, is readily implemented in (35) and (36) on replacingŝ ij byŝ ij þ ıl ij ;v k byv k þ ıx k and A, B, . .…”

Section: Other Variables and Effectsmentioning

confidence: 99%

On material velocities and non-locality in the thermo-mechanics of continua

Goddard

2010

International Journal of Engineering Science

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a b s t r a c tFollowing is a discussion of several issues surrounding the continuum modeling of discrete particulate systems, particularly the uncertainty in the definition of continuum-level material particles and velocities. The work is motivated in part by various proposals for the introduction of supplemental velocity fields into the thermo-mechanics of single-component fluids. A review and modification are given of the relevant continuum field equations, based on the Eulerian rather than the conventional Lagrangian description, and a connection is made to the well-known statistical mechanics of Kirkwood and coworkers for pointparticles.The Noetherian technique of Green and Naghdi is employed to derive the momentum balance directly from the particle-level energy balance, and it is shown that non-barycentric effects in particle motion engender stress asymmetry. It is conjectured that this and related effects are generally bound up with higher-gradient effects and the breakdown of the simple-material model for continuum thermo-mechanics. To illustrate this, a theory of non-local linear viscoelasticity is presented and compared with Brenner's ''bi-velocity hydrodynamics" and Müller's ''extended thermodynamics" for heat flux and stress. These models are shown to represent expansions in spatial wave vector, representing a Knudsen number, and temporal frequency, representing a Deborah number. Suggestions are made for further work to explore the associated effects of couple-stress and the consequences of departures of entropy flux from heat flux.

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“…In the majority of the models, the stress increment is related to the actual stress state of the granular system and its density. This is the case for hypoplasticity [64,68,94,192], where a single non-linear tensorial equation relates the Jaumann stress-rate with strain-rate and stress tensors. Later versions [145] also involve an explicit relation with the structure of the contact network.…”

Section: Continuum Modelingmentioning

confidence: 99%

Micro-macro and jamming transition of polydisperse granular materials

Kumar¹

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Granular hypoplasticity with Cosserat effects

Cited by 10 publications

References 32 publications

A local constitutive model with anisotropy for ratcheting under 2D axial-symmetric isobaric deformation

A local constitutive model with anisotropy for ratcheting under 2D axial-symmetric isobaric deformation

On material velocities and non-locality in the thermo-mechanics of continua

Micro-macro and jamming transition of polydisperse granular materials

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