Molecular dynamics simulations of shock compressed heterogeneous materials. I. The porous case

The propagation of an incident shock and subsequent rarefaction and compression waves in a porous media are analysed from a set of large scale molecular dynamics simulations. The porous material is modelized by a collection of spherical pores, empty or filled with dense gaseous argon, enclosed in a...

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Bibliographic Details
Published in:Journal of applied physics 2015-03, Vol.117 (11)
Main Authors: Soulard, L., Pineau, N., Clérouin, J., Colombet, L.
Format: Article
Language:English
Subjects:
Applied physics
Collapse
Compression waves
Computer simulation
Copper
Longitudinal waves
Mathematical models
Melting points
Molecular dynamics
Pore size
Porosity
Porous materials
Porous media
Rarefaction
Shock wave propagation
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Summary:The propagation of an incident shock and subsequent rarefaction and compression waves in a porous media are analysed from a set of large scale molecular dynamics simulations. The porous material is modelized by a collection of spherical pores, empty or filled with dense gaseous argon, enclosed in a copper matrix. We observe that the pore collapse induces a strong local disorder in the matrix even for shock intensities below the melting point of shocked copper. Various mechanisms are considered and a detailed analysis of the numerical results shows that the melting around an isolated pore is mainly due to the plastic work induced by the collapse: a result that can be extended to more complicated pore shapes. The systematic study of the influence of the shock intensity, the pore size, and the presence of a filling gas shows that the melting is mainly inhibited by the presence of the gas. The final structure strongly depends on the interactions between the waves resulting from the various reflections of the initial shock at the sample boundaries, implying that the evaluation of the incident shock intensity based on post-mortem analyses requires a knowledge of the full history of the sample.
ISSN:0021-8979
1089-7550
DOI:10.1063/1.4914480