Molecular dynamics simulations of jet breakup and ejecta production from a grooved Cu surface under shock loading

An Min He; Pei Wang; Jian Li Shao; Su Qing Duan

doi:10.1088/1674-1056/23/4/047102

Molecular dynamics simulations of jet breakup and ejecta production from a grooved Cu surface under shock loading

An Min He^*, Pei Wang, Jian Li Shao, Su Qing Duan

^*Corresponding author for this work

IAPCM

Research output: Contribution to journal › Article › peer-review

19 Citations (Scopus)

Abstract

Large-scale non-equilibrium molecular dynamics simulations are performed to explore the jet breakup and ejecta production of single crystal Cu with a triangular grooved surface defect under shock loading. The morphology of the jet breakup and ejecta formation is obtained where the ejecta clusters remain spherical after a long simulation time. The effects of shock strength as well as groove size on the steady size distribution of ejecta clusters are investigated. It is shown that the size distribution of ejecta exhibits a scaling power law independent of the simulated shock strengths and groove sizes. This distribution, which has been observed in many fragmentation processes, can be well described by percolation theory.

Original language	English
Article number	047102
Journal	Chinese Physics B
Volume	23
Issue number	4
DOIs	https://doi.org/10.1088/1674-1056/23/4/047102
Publication status	Published - Apr 2014
Externally published	Yes

Keywords

ejection
molecular dynamics

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10.1088/1674-1056/23/4/047102

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title = "Molecular dynamics simulations of jet breakup and ejecta production from a grooved Cu surface under shock loading",

abstract = "Large-scale non-equilibrium molecular dynamics simulations are performed to explore the jet breakup and ejecta production of single crystal Cu with a triangular grooved surface defect under shock loading. The morphology of the jet breakup and ejecta formation is obtained where the ejecta clusters remain spherical after a long simulation time. The effects of shock strength as well as groove size on the steady size distribution of ejecta clusters are investigated. It is shown that the size distribution of ejecta exhibits a scaling power law independent of the simulated shock strengths and groove sizes. This distribution, which has been observed in many fragmentation processes, can be well described by percolation theory.",

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author = "He, {An Min} and Pei Wang and Shao, {Jian Li} and Duan, {Su Qing}",

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T1 - Molecular dynamics simulations of jet breakup and ejecta production from a grooved Cu surface under shock loading

AU - He, An Min

AU - Wang, Pei

AU - Shao, Jian Li

AU - Duan, Su Qing

PY - 2014/4

Y1 - 2014/4

N2 - Large-scale non-equilibrium molecular dynamics simulations are performed to explore the jet breakup and ejecta production of single crystal Cu with a triangular grooved surface defect under shock loading. The morphology of the jet breakup and ejecta formation is obtained where the ejecta clusters remain spherical after a long simulation time. The effects of shock strength as well as groove size on the steady size distribution of ejecta clusters are investigated. It is shown that the size distribution of ejecta exhibits a scaling power law independent of the simulated shock strengths and groove sizes. This distribution, which has been observed in many fragmentation processes, can be well described by percolation theory.

AB - Large-scale non-equilibrium molecular dynamics simulations are performed to explore the jet breakup and ejecta production of single crystal Cu with a triangular grooved surface defect under shock loading. The morphology of the jet breakup and ejecta formation is obtained where the ejecta clusters remain spherical after a long simulation time. The effects of shock strength as well as groove size on the steady size distribution of ejecta clusters are investigated. It is shown that the size distribution of ejecta exhibits a scaling power law independent of the simulated shock strengths and groove sizes. This distribution, which has been observed in many fragmentation processes, can be well described by percolation theory.

KW - ejection

KW - molecular dynamics

UR - http://www.scopus.com/inward/record.url?scp=84899548975&partnerID=8YFLogxK

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DO - 10.1088/1674-1056/23/4/047102

M3 - Article

AN - SCOPUS:84899548975

SN - 1674-1056

VL - 23

JO - Chinese Physics B

JF - Chinese Physics B

IS - 4

M1 - 047102

ER -

Molecular dynamics simulations of jet breakup and ejecta production from a grooved Cu surface under shock loading

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Keywords

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