Shock wave propagation and spall failure in single crystal Mg at atomic scales

被引:0
|
作者
机构
[1] Agarwal, Garvit
[2] Dongare, Avinash M.
来源
Dongare, Avinash M. (dongare@uconn.edu) | 1600年 / American Institute of Physics Inc.卷 / 119期
关键词
Large scale molecular dynamics (MD) simulations are carried out to investigate the wave propagation and failure behavior of single crystal Mg under shock loading conditions. The embedded atom method interatomic potential; used to model the Mg systems; is first validated by comparing the predicted Hugoniot behavior with that observed using experiments. The first simulations are carried out to investigate the effect of loading orientation on the wave propagation and failure behavior by shock loading the system along the [0001] direction (c-axis) and the [1010] direction using a piston velocity of 1500 m/s. The spall strength (peak tensile pressure prior to failure) is predicted to be higher for loading along the [1010] direction than that predicted for loading along the [0001] direction. To investigate the effect of shock pressure on the failure behavior and spall strength of the metal; the MD simulations are carried out using piston velocities of 500 m/s; 1000; m/s; 1500; and 2000 m/s for loading along the c-axis. The results indicate that the higher piston velocities result in higher shock pressures; and the predicted values for the spall strength decrease with an increase in the shock pressure. In addition; the simulations reveal that the various piston velocities result in variations in the interactions between the reflected waves and the tail of the pressure waves and; hence; variations in the failure behavior. In addition; MD simulations are also carried out to investigate the effect of temperature on the wave propagation behavior and spall strength by equilibrating the initial system at temperatures of 300 K; 600; K; and 800 K prior to shock loading simulations using a piston velocity of 1000 m/s. The results suggest a decrease in spall strength of the single crystal metal with an increase in the initial temperature of the system. The strain rates generated; the evolution of temperature; the variations in the wave interactions; and the spall strength computed using MD simulations are discussed and compared to experimental results in the literature. © 2016 AIP Publishing LLC;
D O I
暂无
中图分类号
学科分类号
摘要
Journal article (JA)
引用
收藏
相关论文
共 50 条
  • [1] Shock wave propagation and spall failure in single crystal Mg at atomic scales
    Agarwal, Garvit
    Dongare, Avinash M.
    JOURNAL OF APPLIED PHYSICS, 2016, 119 (14)
  • [2] Dynamic evolution of microstructure during laser shock loading and spall failure of single crystal Al at the atomic scales
    Galitskiy, Sergey
    Ivanov, Dmitry S.
    Dongare, Avinash M.
    JOURNAL OF APPLIED PHYSICS, 2018, 124 (20)
  • [3] Molecular dynamics simulation of shock wave propagation and spall failure in single crystal copper under cylindrical impact
    Chen, Ying
    Jian, Zhiyong
    Xiao, Shifang
    Wang, Liang
    Li, Xiaofan
    Wang, Kun
    Deng, Huiqiu
    Hu, Wangyu
    APPLIED PHYSICS EXPRESS, 2021, 14 (07)
  • [4] Role of pre-existing dislocations on the shock compression and spall behavior in single-crystal copper at atomic scales
    Ma, Ke
    Chen, Jie
    Dongare, Avinash M.
    JOURNAL OF APPLIED PHYSICS, 2021, 129 (17)
  • [5] Shock-induced twinning/detwinning and spall failure in Cu-Ta nanolaminates at atomic scales
    Echeverria, M. J.
    Fensin, S. J.
    Dongare, A. M.
    MODELLING AND SIMULATION IN MATERIALS SCIENCE AND ENGINEERING, 2024, 32 (08)
  • [6] Understanding the plasticity contributions during laser-shock loading and spall failure of Cu microstructures at the atomic scales
    Echeverria, Marco J.
    Galitskiy, Sergey
    Mishra, Avanish
    Dingreville, Remi
    Dongare, Avinash M.
    COMPUTATIONAL MATERIALS SCIENCE, 2021, 198
  • [7] Simulation of shock wave propagation in single crystal and polycrystalline aluminum
    Lloyd, J. T.
    Clayton, J. D.
    Becker, R.
    McDowell, D. L.
    INTERNATIONAL JOURNAL OF PLASTICITY, 2014, 60 : 118 - 144
  • [8] Spall damage in single crystal tin under shock wave loading: A molecular dynamics simulation
    Wang, Xin-Xin
    He, An-Min
    Zhou, Ting-Ting
    Wang, Pei
    MECHANICS OF MATERIALS, 2021, 160
  • [9] Role of nanoscale Cu/Ta interfaces on the shock compression and spall failure of nanocrystalline Cu/Ta systems at the atomic scales
    Chen, Jie
    Tschopp, Mark A.
    Dongare, Avinash M.
    JOURNAL OF MATERIALS SCIENCE, 2018, 53 (08) : 5745 - 5765
  • [10] Role of nanoscale Cu/Ta interfaces on the shock compression and spall failure of nanocrystalline Cu/Ta systems at the atomic scales
    Jie Chen
    Mark A. Tschopp
    Avinash M. Dongare
    Journal of Materials Science, 2018, 53 : 5745 - 5765
12345