Litcius/Paper detail

Combined numerical and experimental study of microstructure and permeability in porous granular media

Philipp Eichheimer, Marcel Thielmann, Wakana Fujita, Gregor Golabek, Michihiko Nakamura, Satoshi Okumura, Takayuki Nakatani, Maximilian O. Kottwitz

2020Solid Earth30 citationsDOIOpen Access PDF

Abstract

Abstract. Fluid flow on different scales is of interest for several Earth science disciplines like petrophysics, hydrogeology and volcanology. To parameterize fluid flow in large-scale numerical simulations (e.g. groundwater and volcanic systems), flow properties on the microscale need to be considered. For this purpose experimental and numerical investigations of flow through porous media over a wide range of porosities are necessary. In the present study we sinter glass bead media with various porosities and measure the permeability experimentally. The microstructure, namely effective porosity and effective specific surface, is investigated using image processing. We determine flow properties like tortuosity and permeability using numerical simulations. We test different parameterizations for isotropic low-porosity media on their potential to predict permeability by comparing their estimations to computed and experimentally measured values.

Topics & Concepts

TortuosityMicroscale chemistryPorous mediumHydrogeologyPermeability (electromagnetism)PorosityGeologyIsotropyMaterials scienceGeotechnical engineeringMicrostructurePetrophysicsRelative permeabilityComputer simulationMineralogyMechanicsComposite materialOpticsMathematicsChemistryPhysicsBiochemistryMembraneMathematics educationLattice Boltzmann Simulation StudiesHeat and Mass Transfer in Porous MediaGroundwater flow and contamination studies