The micromechanical behaviors of coral sands remain poorly understood, primarily due to the inherent complexity of their highly irregular particle shapes, which pose significant difficulties for accurate three-dimensional (3D) particle reconstruction and tracking using Xray tomography (μCT). To address these challenges, this study proposes a novel framework that integrates large vision models (LVMs) for efficient and accurate 3D particle reconstruction with optimal transport (OT) for robust particle tracking. This framework is validated through in situ mini-triaxial tests on coral sands with μCT. Compared with the state-of-the-art (SOTA) method, the proposed approach achieves comparable reconstruction accuracy (90%) while reducing computational time by 50%. For particle tracking, accuracy between adjacent μCT scans (corresponding to axial strain increments of 2.5%, 5%, and 10%) reached 95%, 86%, and 71%, respectively. Micromechanical analysis of coral sands further reveals that heterogeneous local shear deformation develops as axial strain increases, forming an X-shaped shear band. Significant fabric anisotropy emerges after peak stress, with preferred orientations aligning with the shear band. Moreover, particle breakage was observed to occur primarily during the strain-softening stage. Splitting induced by stress concentration was the predominant failure mode.
Shaoheng He (Thu,) studied this question.