Abstract
Poroelasticity theory predicts wave velocities in a saturated porous medium through a coupling between the bulk deformation of the solid skeleton and porous fluid flow. The challenge emerges below the characteristic wavelengths at which hydrodynamic interactions between grains and pore fluid become important. We investigate the pressure and volume fraction dependence of compressional- and shear-wave velocities in fluid-saturated, random, isotropic, frictional granular packings. The lattice Boltzmann method (LBM) and discrete element method (DEM) are two-way coupled to capture the particle-pore fluid interactions; an acoustic source is implemented to insert a traveling wave from the fluid reservoir to the saturated medium. We extract wave velocities from the acoustic branches in the wavenumber-frequency space, for a range of confining pressures and volume fractions. For random isotropic granular media the pressure-wave velocity data collapse on a single curve when scaled properly by the volume fraction.
Highlights
Understanding wave propagation in saturated granular media is vital for non-destructive soil testing, seismic inversion and oil exploration, among others
While conventional computational fluid dynamics methods are sufficient for modeling dilute suspensions of particles, direct numerical simulation techniques, such as the coupled lattice Boltzmann-discrete element method (LBM-DEM), are better suited for wave modeling because it captures the fluid flow and particle-fluid interactions at thepore scale
As a first test for lattice Boltzmann method (LBM)-DEM modeling framework, we explore the dependence of wave velocities on volume fraction
Summary
Understanding wave propagation in saturated granular media is vital for non-destructive soil testing, seismic inversion and oil exploration, among others. We investigate the pressure and volume fraction dependence of compressional- and shear-wave velocities in fluid-saturated, random, isotropic, frictional granular packings. We extract wave velocities from the acoustic branches in the wavenumber-frequency space, for a range of confining pressures and volume fractions.
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