Hydro-micromechanical modeling of wave propagation in saturated granular media

TL;DR

This paper introduces a novel hydro-micromechanical model coupling LBM and DEM to simulate wave propagation in saturated granular media, capturing microstructural effects beyond Biot's classical theory.

Contribution

The study develops a coupled LBM-DEM numerical model that accounts for particle-fluid interactions at the microscale during wave propagation in saturated granular materials.

Findings

Model accurately predicts wave velocities matching Biot's theory.

Simulation captures pressure, shear, and slow compressional waves.

Effects of wave frequency and waveform on dispersion are analyzed.

Abstract

Biot's theory predicts the wave velocities of a saturated poroelastic granular medium from the elastic properties, density and geometry of its dry solid matrix and the pore fluid, neglecting the interaction between constituent particles and local flow. However, when the frequencies become high and the wavelengths comparable with particle size, the details of the microstructure start to play an important role. Here, a novel hydro-micromechanical numerical model is proposed by coupling the lattice Boltzmann method (LBM) with the discrete element method (DEM. The model allows to investigate the details of the particle-fluid interaction during propagation of elastic waves While the DEM is tracking the translational and rotational motion of each solid particle, the LBM can resolve the pore-scale hydrodynamics. Solid and fluid phases are two-way coupled through momentum exchange. The coupling scheme is benchmarked with the terminal velocity of a single sphere settling in a fluid. To mimic a pressure wave entering a saturated granular medium, an oscillating pressure boundary condition on the fluid is implemented and benchmarked with one-dimensional wave equations. Using a face centered cubic structure, the effects of input waveforms and frequencies on the dispersion relations are investigated. Finally, the wave velocities at various effective confining pressures predicted by the numerical model are compared with with Biot's analytical solution, and a very good agreement is found. In addition to the pressure and shear waves, slow compressional waves are observed in the simulations, as predicted by Biot's theory.