Please use this identifier to cite or link to this item: http://hdl.handle.net/10397/119684
Title: The compressibility of kaolin clay : a micromechanical perspective based on DEM
Authors: Liu, B 
Yin, ZY 
Hicher, PY
Issue Date: 2026
Source: Canadian geotechnical journal, 2026, v. 63, p. 1-19
Abstract: The mechanisms governing the compressibility of kaolin clays are investigated through discrete element method simulations of oedometer tests, where clay platelets are modelled as clumps of spheres. A contact model incorporating the long-range van der Waals (VDW) attraction and electrical double layer (EDL) repulsion, alongside mechanical forces, is formulated to reproduce interplatelet physicochemical forces in agreement with the DLVO theory. Oedometer simulations are conducted on assemblies of platelet particles with varying aspect ratios. The significance of different interparticle forces is evaluated by partitioning the total stress into different contributions, revealing that while the EDL interaction is negligible for practical stress levels, the VDW interaction induces tensile stresses comparable to mechanical forces at compression stresses up to 15–70 kPa. As compression stress increases, the significance of the physicochemical interactions decreases, while mechanical contact forces become increasingly dominant. Additionally, increasing the VDW force or decreasing the EDL force leads to increased stress from mechanical contact forces, consistent with the modified effective stress concept. After sedimentation, the clay platelets initially form an open-flocculated structure with edge-to-face association dominating the fabric. Upon compression, the platelets tend to rotate their normal vectors towards the compression direction and aggregate into a face-to-face arrangement.
Keywords: Aspect ratio
Clay compressibility
Discrete element method
Electric double layer
Van der Waals force
Publisher: Canadian Science Publishing
Journal: Canadian geotechnical journal 
ISSN: 0008-3674
EISSN: 1208-6010
DOI: 10.1139/cgj-2024-0724
Rights: © 2026 The Authors. Permission for reuse (free in most cases) can be obtained from copyright.com (https://marketplace.copyright.com/rs-ui-web/mp).
This is the accepted version of the work. The final published article is available at https://doi.org/10.1139/cgj-2024-0724.
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