Stress anisotropy and wave propagation: a micromechanical view

Laboratory geophysics tests including bender elements and acoustic emission measure the speed of propagation of stress or sound waves in granular materials to derive elastic stiffness parameters. This contribution builds on earlier studies to assess whether the received signal characteristics can provide additional information about either the material's behaviour or the nature of the material itself. Specifically it considers the maximum frequency that the material can transmit; it also assesses whether there is a simple link between the spectrum of the received signal and the natural frequencies of the sample. Discrete element method (DEM) simulations of planar compression wave propagation were performed to generate the data for the study. Restricting consideration to uniform (monodisperse) spheres, the material fabric was varied by considering face-centred cubic lattice packings as well as random configurations with different packing densities. Supplemental analyses, in addition to the DEM simulations, were used to develop a more comprehensive understanding of the system dynamics. The assembly stiffness and mass matrices were extracted from the DEM model and these data were used in an eigenmode analysis that provided significant insight into the observed overall dynamic response. The close agreement of the wave velocities estimated using eigenmode analysis with the DEM results confirms that DEM wave propagation simulations can reliably be used to extract material stiffness data. The data show that increasing either stress or density allows higher frequencies to propagate through the media, but the low-pass wavelength is a function of packing density rather than stress level. Prior research which had hypothesised that there is a simple link between the spectrum of the received signal and the natural sample frequencies was not substantiated.

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“…[4,5]) or frequency domain techniques (e.g. [6][7][8][9]). This paper explores whether additional information, i.e.…”

Section: Introductionmentioning

confidence: 99%

Influence of packing density and stress on the dynamic response of granular materials

et al. 2017

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“…(Note that the effect of small geometrical perturbations of the lattice is considered by O'Sullivan et al [19] and Velicky and Caroli [20].) Also relevant is the analytical work of Santamarina and Cascante [26], who considered the stiffness of regular packings of monodisperse and polydisperse spheres. Their work included a review of the analytical relations between fabric, grain properties and the effective overall system for threedimensional regular assemblies of uniform spheres.…”

Section: Simulation Approachmentioning

confidence: 99%

“…They observed similarities between the response trends predicted analytically for ideal systems and empirical relationships derived for real physical soils. Just as in the case of the work by [26], the system chosen for consideration here is very stable and, under small perturbations, there is no change in contact configuration, i.e. the material can be considered elastic as plasticity is associated with contact breakage and sliding (in the absence of grain breakage).…”

Section: Simulation Approachmentioning

confidence: 99%

Two-dimensional discrete element modelling of bender element tests on an idealised granular material

2012

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The small-strain (elastic) shear stiffness of soil is an important parameter in geotechnics. It is required as an input parameter to predict deformations and to carry out site response analysis to predict levels of shaking during earthquakes. Bender element testing is often used in experimental soil mechanics to determine the shear (S-) wave velocity in a given soil and hence the shear stiffness. In a bender element test a small perturbation is input at a point source and the propagation of the perturbation through the system is measured at a single measurement point. The mechanics and dynamics of the system response are non-trivial, complicating interpretation of the measured signal. This paper presents the results of a series of discrete element method (DEM) simulations of bender element tests on a simple, idealised granular material. DEM simulations provide the opportunity to study the mechanics of this testing approach in detail. The DEM model is shown to be capable of capturing features of the system response that had previously been identified in continuum-type analyses of the system. The propagation of the wave through the sample can be monitored at the particlescale in the DEM simulation. In particular, the particle velocity data indicated the migration of a central S-wave accompanied by P-waves moving along the sides of the sample. The elastic stiffness of the system was compared with the stiffness calculated using different approaches to interpreting bender element test data. An approach based upon direct decomposition of the signal using a fast-Fourier transform yielded the most accurate results.

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“…Theoretical solutions such as the Hertz-Mindlin contact theory are available to relate the small strain shear modulus to microscopic properties like particle stiffness and Poisson's ratio, void ratio, and coordination number [3]. For regular packing assemblies, Fig.…”

Section: Introductionmentioning

confidence: 99%

The influence of void ratio on small strain shear modulus of granular materials: A micromechanical perspective

Xu¹,

Cheng²,

LING³

2013

AIP Conference Proceedings

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Stress anisotropy and wave propagation: a micromechanical view

Cited by 116 publications

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Influence of packing density and stress on the dynamic response of granular materials

Influence of packing density and stress on the dynamic response of granular materials

Two-dimensional discrete element modelling of bender element tests on an idealised granular material

The influence of void ratio on small strain shear modulus of granular materials: A micromechanical perspective

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