Exploring the Macroscopic Behavior and Microstructure Evolution of Lightly Cemented Sand in the Post-Liquefaction Process Using DEM

Exploring the Macroscopic Behavior and Microstructure Evolution of Lightly Cemented Sand in the Post-Liquefaction Process Using DEM

This study investigates the post-liquefaction monotonic undrained shearing behavior of cemented sand at the macro- and microscales, using the discrete element method. A series of cyclic undrained triaxial tests with different stress amplitudes and post-liquefaction monotonic undrained triaxial tests...

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Bibliographic Details
Published in:Materials Vol. 17; no. 15; p. 3721
Main Authors: Zhang, Fuguang, Chen, Cheng, Feng, Huaiping
Format: Journal Article
Language:English
Published: Switzerland MDPI AG 27-07-2024
Subjects:
Bonding
cemented sand
Contact pressure
Contact stresses
Coordination numbers
Discrete element method
discrete element modeling
Earthquakes
Liquefaction
micromechanism
Microstructure
post-liquefaction behavior
Sand
Shear strain
Shear strength
Shearing
Simulation
Stiffness
Stress ratio
Tomography
Triaxial tests
micromechanism
cemented sand
post-liquefaction behavior
discrete element modeling
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Summary:This study investigates the post-liquefaction monotonic undrained shearing behavior of cemented sand at the macro- and microscales, using the discrete element method. A series of cyclic undrained triaxial tests with different stress amplitudes and post-liquefaction monotonic undrained triaxial tests were simulated on cemented sand with diverse cement contents (CCs). For comparison, a series of monotonic undrained triaxial tests on cemented sand without liquefaction (virgin cemented sand) were also modeled. The macroscopic behavior was analyzed in conjunction with the microscopic characteristics of the assembly, such as the deviator fabric of contact normal orientation, mechanical coordination number, energy components, and bond breakage. The results show that the DEM model can capture the effect of CC and cyclic stress ratio (CSR) on the undrained shear strength, stiffness, and pore pressure observed in laboratory experiments. Referring to the virgin specimen, with an increase in CC, the mechanical coordination number and the input work increment increase, while the deviator fabric for total contacts changes irregularly, leading to a greater initial stiffness and shear strength. In the case of the liquefied specimen, the smaller initial mechanical coordination number results in a very low initial stiffness regardless of CC. Contrary to the uncemented sand, both the mechanical coordination number and the input work increment decrease with an increasing CSR for the cemented sand. The microstructure evolution governs the effect of cementation level and liquefaction history on the macroscopic post-liquefaction behavior.
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ISSN:1996-1944
1996-1944
DOI:10.3390/ma17153721