Molecular Dynamics Simulations of the Interactions Between Tungsten Dust and Beryllium Plasma-Facing Material

被引:0
|
作者
牛国鉴 [1 ,2 ]
李小椿 [1 ]
徐倩 [1 ]
杨钟时 [1 ]
罗广南 [1 ]
机构
[1] Institute of Plasma Physics,Chinese Academy of Sciences
[2] University of Science and Technology of China
来源
Plasma Science and Technology | 2015年 / 12期
基金
中国国家自然科学基金;
关键词
molecular dynamics; tokamaks; dust; plasma-facing materials;
D O I
暂无
中图分类号
O53 [等离子体物理学];
学科分类号
070204 ;
摘要
In the present research,molecular dynamics simulation is applied to study the interactions between tungsten dusts and a beryllium plasma-facing material surface.Calculation results show that it is quite difficult for nanometer-size dust particles to damage the plasma-facing material surface,which is different from the micrometer-size ones.The reason may be the size difference between dust and crystal grains.The depth of dust penetration into plasma-facing materials is closely related to the incident velocity,and the impacting angle also plays an important role.Dust and material surface damage is also investigated.Results show that both incident velocity and angle can significantly influence the damage.
引用
收藏
页码:1072 / 1077
页数:6
相关论文
共 50 条
  • [31] Helium flux effects on bubble growth and surface morphology in plasma-facing tungsten from large-scale molecular dynamics simulations
    Hammond K.D.
    Naeger I.V.
    Widanagamaachchi W.
    Lo L.-T.
    Maroudas D.
    Wirth B.D.
    Nuclear Fusion, 2019, 59 (06):
  • [32] RECENT ADVANCES ON HYDROGEN RETENTION IN ITER'S PLASMA-FACING MATERIALS: BERYLLIUM, CARBON, AND TUNGSTEN
    Skinner, C. H.
    Haasz, A. A.
    Alimow, V. Kh.
    Bekris, N.
    Causey, R. A.
    Clark, R. E. H.
    Coad, J. P.
    Davis, J. W.
    Doerner, R. P.
    Mayer, M.
    Pisarev, A.
    Roth, J.
    Tanabe, T.
    FUSION SCIENCE AND TECHNOLOGY, 2008, 54 (04) : 891 - 945
  • [33] INTERPRETATION OF DEUTERIUM PUMPING BY PLASMA-FACING BERYLLIUM SURFACES
    ANDREW, PL
    PEACOCK, AT
    PICK, MA
    JOURNAL OF NUCLEAR MATERIALS, 1992, 196 : 997 - 1001
  • [34] Impact of water ingress on deuterium release, oxidation, and dust generation in beryllium plasma-facing components
    Zayachuk, Y.
    Catarino, N.
    Smith, C.
    Jepu, I.
    Ayres, C.
    Widdowson, A.
    Alves, E.
    Rubel, M.
    NUCLEAR MATERIALS AND ENERGY, 2023, 35
  • [35] PROPERTIES AND PERFORMANCE OF BERYLLIUM AND CARBON FOR PLASMA-FACING COMPONENTS
    DIETZ, KJ
    FUSION TECHNOLOGY, 1991, 19 (04): : 2031 - 2034
  • [36] THERMAL FATIGUE TESTS OF VACUUM PLASMA-SPRAYED TUNGSTEN TILES FOR PLASMA-FACING MATERIAL
    Chong, F. L.
    Chen, J. L.
    Zheng, X. B.
    FUSION SCIENCE AND TECHNOLOGY, 2012, 61 (03) : 236 - 239
  • [37] Outgassing from and deuterium retention in beryllium and Be/C mixed-material plasma-facing components
    Doerner, RP
    Conn, RW
    Luckhardt, SC
    Sze, FC
    Won, J
    FUSION ENGINEERING AND DESIGN, 2000, 49-50 : 183 - 188
  • [38] Microstructure and performance of rare earth element-strengthened plasma-facing tungsten material
    Luo, Laima
    Shi, Jing
    Lin, Jinshan
    Zan, Xiang
    Zhu, Xiaoyong
    Xu, Qiu
    Wu, Yucheng
    SCIENTIFIC REPORTS, 2016, 6
  • [39] Tungsten heavy alloy: an alternative plasma-facing material in terms of hydrogen isotope retention
    Maier, H.
    Neu, R.
    Schwarz-Selinger, T.
    von Toussaint, U.
    Manhard, A.
    Duerbeck, T.
    Hunger, K.
    NUCLEAR FUSION, 2020, 60 (12)
  • [40] EVALUATION OF TUNGSTEN AS A PLASMA-FACING MATERIAL FOR STEADY-STATE MAGNETIC FUSION DEVICES
    HIROOKA, Y
    BOURHAM, M
    BROOKS, JN
    CAUSEY, RA
    CHEVALIER, G
    CONN, RW
    EDDY, WH
    GILLIGAN, J
    KHANDAGLE, M
    RA, Y
    JOURNAL OF NUCLEAR MATERIALS, 1992, 196 : 149 - 158
12345