MS 83: Multiscale Digital Rock and Granular Physics
WaiChing Sun*, Columbia University, USA
Teng-fong Wong, The Chinese University of Hong Kong, Hong Kong
Mario Martinez, Sandia National Laboratories, USA
Xiaoyu Song, University of Florida, USA
The mechanical, hydraulic and thermal properties of unsaturated geomaterials are strongly influenced by the micro-mechanical liquid-gas-solid interactions occurring in the pore space. As a result, understanding how microstructural attributes evolve is the key step to characterizing macroscopic responses of geomaterials. This MS is aimed at providing a forum for both modelers and experimentalists to exchange ideas on digital rock physics – a technique that infers or estimates macroscopic material responses directly from pore structures inferred from digital images. In particular, we seek contributions on innovative usage of micro-CT imaging techniques for geomaterials, applications of 3D printing techniques to study single- and dual-porosity systems, and analytical and numerical techniques that predict fluid-induced micromechanical responses of porous media, and the multiscale homogenization techniques that connects microstructural attributes to field-scale simulations.
News about Computational Poromechanics lab at Columbia University.