Simulation of particle ejecta effects from the surface under impulse action

Simulation of particle ejecta effects from the surface under impulse action

•We consider the process of ejecta of particles from the surface under impact loading of solid body.•We used 3D modeling by cluster dynamics and one-dimensional modeling by chains of clusters.•We found side effects dusting are caused by anharmonicity of potentials.•Side effects eliminated by modifyi...

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Bibliographic Details
Published in:Communications in nonlinear science & numerical simulation Vol. 19; no. 3; pp. 638 - 648
Main Authors: Piskunov, V.N., Tsaplin, D.V., Veselov, R.А.
Format: Journal Article
Language:English
Published: Elsevier B.V 01-03-2014
Subjects:
3D simulations
Anharmonicity
Cluster dynamics (CD) method
Cluster motion equations
Ejecta
One-dimensional particle chain
Plane shock wave
Potential anharmonicity
Short-range and long-range potentials
Smooth surface
Cluster dynamics (CD) method
Ejecta
One-dimensional particle chain
Cluster motion equations
3D simulations
Short-range and long-range potentials
Plane shock wave
Smooth surface
Potential anharmonicity
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Summary:•We consider the process of ejecta of particles from the surface under impact loading of solid body.•We used 3D modeling by cluster dynamics and one-dimensional modeling by chains of clusters.•We found side effects dusting are caused by anharmonicity of potentials.•Side effects eliminated by modifying the equations of motion.•The proposed approach can be used to solve practical problems and to separate the physical effects from computing mystification. This paper presents research results of ejecta due to plane shock wave arrival at a free smooth surface of a homogeneous pattern in the cluster dynamics (CD) simulation. Provided are 3D simulation results illustrating that ejecta effect is not only due to the physical reasons but also due to the side computation effects. One-dimensional model is developed to study the problems of cluster motion. This model was used to analyze the cluster behavior when a shock wave arrives at the boundary of the pattern. The oscillation character of the near-boundary clusters was analyzed as well as the impact of the interaction potential anharmonicity. It is shown that the most high-frequency mode of oscillations of the cluster lattice defined by potential anharmonicity (with neighbors moving in opposite phase) plays an important role in side ejecta effects. Hence, the criteria was developed to define the threshold loading velocity associated with ejecta in 3D problems. The method is suggested to eliminate the ejecta computation effects using the modification of cluster motion equations. The efficiency of this method is verified in a number of 3D simulations. It is shown that the suggested approach eliminates the side ejecta effects and keeps the fundamental physical regularities of loading and further motion of the pattern.
Bibliography:ObjectType-Article-2
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content type line 23
ISSN:1007-5704
1878-7274
DOI:10.1016/j.cnsns.2013.06.027