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Autori principali: Vyas, Dhairya R., Ottino, Julio M., Lueptow, Richard M., Umbanhowar, Paul B.
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2410.14798
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author Vyas, Dhairya R.
Ottino, Julio M.
Lueptow, Richard M.
Umbanhowar, Paul B.
author_facet Vyas, Dhairya R.
Ottino, Julio M.
Lueptow, Richard M.
Umbanhowar, Paul B.
contents The Discrete Element Method is widely employed for simulating granular flows, but conventional integration techniques may produce unphysical results for simulations with static friction when particle size ratios exceed $R \approx 3$. These inaccuracies arise because some variables in the velocity-Verlet algorithm are calculated at the half-timestep, while others are computed at the full timestep. To correct this, we develop an improved velocity-Verlet integration algorithm to ensure physically accurate outcomes up to the largest size ratios examined ($R=100$). The implementation of this improved integration method within the LAMMPS framework is detailed, and its effectiveness is validated through a simple three-particle test case and a more general example of granular flow in mixtures with large size-ratios, for which we provide general guidelines for selecting simulation parameters and accurately modeling inelasticity in large particle size-ratio simulations.
format Preprint
id arxiv_https___arxiv_org_abs_2410_14798
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Improved Velocity-Verlet Algorithm for the Discrete Element Method
Vyas, Dhairya R.
Ottino, Julio M.
Lueptow, Richard M.
Umbanhowar, Paul B.
Computational Physics
The Discrete Element Method is widely employed for simulating granular flows, but conventional integration techniques may produce unphysical results for simulations with static friction when particle size ratios exceed $R \approx 3$. These inaccuracies arise because some variables in the velocity-Verlet algorithm are calculated at the half-timestep, while others are computed at the full timestep. To correct this, we develop an improved velocity-Verlet integration algorithm to ensure physically accurate outcomes up to the largest size ratios examined ($R=100$). The implementation of this improved integration method within the LAMMPS framework is detailed, and its effectiveness is validated through a simple three-particle test case and a more general example of granular flow in mixtures with large size-ratios, for which we provide general guidelines for selecting simulation parameters and accurately modeling inelasticity in large particle size-ratio simulations.
title Improved Velocity-Verlet Algorithm for the Discrete Element Method
topic Computational Physics
url https://arxiv.org/abs/2410.14798