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Many geotechnical problems involve large deformations, non-linear material behaviour, soil-structure interactions, and multiphase (solid, liquid, gas) interactions, which poses significant challenges for numerical simulations. The material point method (MPM) showed to be well suited to study slope instabilities, such as landslides, earth embankment and levee failures, underground excavations, explosions, soil-penetration problems, such as pile installation, Cone Penetration Testing, Free Fall Penetrometer testing, etc. Moreover, erosion and sedimentation problems require considering phase transitions (from solid-like to fluid-like), and This contribution will show the latest numerical developments of MPM with respect to the above-mentioned aspects as implemented in the open-source software Anura3D. Particular attention is given to some geotechnical applications, such as the simulation of slope collapse due to earthquake or water pressure changes, erosion problems, porous sea defences, installation problems, and many more.
Published on 15/02/22
Accepted on 15/02/22
Submitted on 15/02/22
Volume IS20 - The Material Point Method – Recent Advances, 2022
DOI: 10.23967/particles.2021.012
Licence: CC BY-NC-SA license
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