Simulation of the Pore Formation at Grain Boundaries in Aluminum

被引:4
|
作者
Weckman, A., V [1 ]
Dem'yanov, B. F. [1 ]
机构
[1] Polzunov Altai State Tech Univ, Barnaul 656038, Russia
来源
JETP LETTERS | 2020年 / 111卷 / 11期
关键词
PRESSURE; VACANCIES; EVOLUTION; GROWTH; COPPER; CREEP;
D O I
10.1134/S0021364020110119
中图分类号
O4 [物理学];
学科分类号
0702 ;
摘要
The possibility of the pore formation at the tilt grain boundaries with the [100] misorientation axis is studied by computer simulation methods. Three special boundaries and three grain boundaries of a general type are studied at temperatures of 400, 500, and 600 K. It is shown that the presence of 3% lattice vacancies is insufficient for the pore formation both at the grain boundary and in grains, whereas in the presence of 6% lattice vacancies, pores are formed only in grains. Pores on grain boundaries are formed at temperatures of 500 and 600 K with a lattice vacancy concentration of 4 and 5%, respectively. Pores are not formed on a special grain boundary sigma 5(013).
引用
收藏
页码:643 / 646
页数:4
相关论文
共 50 条
  • [41] Pore Formation and Shape Control Simulation of Lotus Aluminum by the Phase-Field Method
    Takahashi, Kei
    Sasajima, Yasushi
    Ikeda, Teruyuki
    ACS OMEGA, 2022, 7 (17): : 14985 - 14993
  • [42] Molecular static simulation of the effect of alkaline metal impurities on the bonding of Al atoms at the grain boundaries of aluminum
    Tu, G
    Itoh, A
    Kyuno, K
    Yamamoto, R
    INTERFACIAL ENGINEERING FOR OPTIMIZED PROPERTIES, 1997, 458 : 227 - 230
  • [43] Grain boundary sliding and accommodation in aluminum tricrystal with a `pore'
    Sisanbaev, A.V.
    Valiev, R.Z.
    Shalimova, A.V.
    Materials Science Forum, 1994, 170-172 : 101 - 106
  • [44] Pore Formation Upon Nitriding Iron and Iron-Based Alloys: The Role of Alloying Elements and Grain Boundaries
    B. Schwarz
    H. Göhring
    S. R. Meka
    R. E. Schacherl
    E. J. Mittemeijer
    Metallurgical and Materials Transactions A, 2014, 45 : 6173 - 6186
  • [45] Pore Formation Upon Nitriding Iron and Iron-Based Alloys: The Role of Alloying Elements and Grain Boundaries
    Schwarz, B.
    Goehring, H.
    Meka, S. R.
    Schacherl, R. E.
    Mittemeijer, E. J.
    METALLURGICAL AND MATERIALS TRANSACTIONS A-PHYSICAL METALLURGY AND MATERIALS SCIENCE, 2014, 45A (13): : 6173 - 6186
  • [46] SIMULATION OF SOLUTE SEGREGATION TO GRAIN-BOUNDARIES
    WETZEL, JT
    MACHLIN, ES
    JOURNAL OF METALS, 1983, 35 (08): : A24 - A24
  • [47] SIMULATION OF RANDOM WANDERINGS ON GRAIN-BOUNDARIES
    GORBUNOV, DA
    KLINGER, LM
    FIZIKA METALLOV I METALLOVEDENIE, 1986, 61 (06): : 1084 - 1088
  • [48] Effect of grain boundary dislocations on the sliding resistance of σ11 grain boundaries in aluminum
    Kurtz, RJM
    Hoagland, RG
    SCRIPTA MATERIALIA, 1998, 39 (4-5) : 653 - 659
  • [49] CRACK FORMATION ALONG GRAIN-BOUNDARIES
    HORACSEK, O
    BARTHA, L
    PLANSEEBERICHTE FUR PULVERMETALLURGIE, 1977, 25 (03): : 157 - 167
  • [50] Formation process of skyrmion lattice domain boundaries: The role of grain boundaries
    Nakajima, H.
    Kotani, A.
    Mochizuki, M.
    Harada, K.
    Mori, S.
    APPLIED PHYSICS LETTERS, 2017, 111 (19)
12345