Litcius/Paper detail

Particle morphology and principal stress direction dependent strength anisotropy through torsional shear testing

Shao-Heng He, Zhen‐Yu Yin, Zhi Ding, Ruidong Li

2024Canadian Geotechnical Journal30 citationsDOI

Abstract

The major principal stress direction angle ( α σ ) experienced by granular soils varies widely in engineering, causing different strengths. However, how particle morphology affects the strength anisotropy behavior under different α σ remains unclear. To address this gap, this study performed drained hollow cylinder torsional shear tests under different α σ on six granular materials with distinct morphologies. Results highlight the significant dependence of peak strengths of granular materials on both particle morphology and α σ . Increasing particle shape irregularity and surface roughness leads to a considerable enhancement in peak strength, while this peak strength significantly degrades with increasing α σ . Materials with more irregular shapes were found to have a more pronounced strength anisotropy. Furthermore, the initial fabric of particle packings, derived from three-dimensional X-ray microtomography, was used to interpret microscopic mechanisms behind the morphology-dependent strength anisotropy. Irregular-shaped materials display broader preferred particle orientations and higher initial fabric anisotropy compared to relatively regular-shaped materials. This higher morphology-induced fabric anisotropy contributes to strength anisotropy, and a correlation was established for describing this trend. Additionally, an anisotropic failure criterion incorporating fabric anisotropy was developed to characterize the strength envelope for granular materials with diverse shapes.

Topics & Concepts

Geotechnical engineeringAnisotropyPrincipal stressDirect shear testMaterials scienceShear strength (soil)Triaxial shear testShear stressStrength theoryShear (geology)Stress (linguistics)GeologyStructural engineeringComposite materialEngineeringPhysicsSoil waterSoil sciencePhilosophyQuantum mechanicsLinguisticsGeotechnical Engineering and Soil MechanicsLandslides and related hazardsGranular flow and fluidized beds