Stacking fault energy of cryogenic austenitic steels

被引:105
|
作者
Dai, QX [1 ]
Wang, AD [1 ]
Cheng, XN [1 ]
Luo, XM [1 ]
机构
[1] Jiangsu Univ, Sch Mat Sci & Engn, Zhenjiang 212013, Peoples R China
来源
CHINESE PHYSICS | 2002年 / 11卷 / 06期
关键词
austenitic steels; stacking fault energy; alloying element;
D O I
10.1088/1009-1963/11/6/315
中图分类号
O4 [物理学];
学科分类号
0702 ;
摘要
Stacking fault energy and stacking fault nucleation energy are defined in terms of the physical nature of stacking faults and stacking fault energy, and the measuring basis for stacking fault energy. Large quantities of experimental results are processed with the aid of a computer and an expression for calculating stacking fault energy has been obtained as gamma(SF)(300)(mJ.m(-2))=gamma(SF)(0) + 1.59Ni - 1.34Mn + 0.06Mn(2) - 1.75Cr + 0.01Cr(2) + 15.21Mo - 5.59Si - 60.69(C + 1.2N)(Cr + Mn + Mo)(1/2) + 0.61[Ni . (Cr + Mn)](1/2).
引用
下载
收藏
页码:596 / 600
页数:5
相关论文
共 50 条
  • [1] TWIN FREQUENCY AND STACKING FAULT ENERGY IN AUSTENITIC STEELS
    SILCOCK, JM
    ROOKES, RW
    BARFORD, J
    JOURNAL OF THE IRON AND STEEL INSTITUTE, 1966, 204 : 623 - &
  • [2] Thermodynamic modeling of the stacking fault energy of austenitic steels
    Curtze, S.
    Kuokkala, V. -T.
    Oikari, A.
    Talonen, J.
    Hanninen, H.
    ACTA MATERIALIA, 2011, 59 (03) : 1068 - 1076
  • [3] Stacking fault energy and magnetism in austenitic stainless steels
    Vitos, L.
    Korzhavyi, P. A.
    Nilsson, J-O
    Johansson, B.
    PHYSICA SCRIPTA, 2008, 77 (06)
  • [4] Effect of Carbon and Nitrogen on the Stacking Fault Energy in Austenitic Steels
    Blinov, V. M.
    Glezer, A. M.
    Bannykh, I. O.
    Lukin, E. I.
    Blinova, E. N.
    Bannykh, O. A.
    Blinov, E. V.
    Chernogorova, O. P.
    Samoilova, M. A.
    Chernenok, D. V.
    RUSSIAN METALLURGY, 2022, 2022 (04): : 347 - 354
  • [5] STACKING-FAULT ENERGY IN AUSTENITIC STAINLESS-STEELS
    RHODES, CG
    THOMPSON, AW
    JOM-JOURNAL OF METALS, 1976, 28 (12): : A39 - A39
  • [6] The deformation of low-stacking-fault-energy austenitic steels
    Karaman, I.
    Sehitoglu, H.
    Chumlyakov, Y.I.
    Maier, H.J.
    JOM, 2002, 54 (07) : 31 - 37
  • [7] The deformation of low-stacking-fault-energy austenitic steels
    I. Karaman
    H. Sehitoglu
    Y. I. Chumlyakov
    H. J. Maier
    JOM, 2002, 54 : 31 - 37
  • [8] Effect of Carbon and Nitrogen on the Stacking Fault Energy in Austenitic Steels
    V. M. Blinov
    A. M. Glezer
    I. O. Bannykh
    E. I. Lukin
    E. N. Blinova
    O. A. Bannykh
    E. V. Blinov
    O. P. Chernogorova
    M. A. Samoilova
    D. V. Chernenok
    Russian Metallurgy (Metally), 2022, 2022 : 347 - 354
  • [9] Effect of Substitutional Alloying Elements on the Stacking Fault Energy in Austenitic Steels
    V. M. Blinov
    I. O. Bannykh
    E. I. Lukin
    O. A. Bannykh
    E. V. Blinov
    O. P. Chernogorova
    M. A. Samoilova
    Russian Metallurgy (Metally), 2021, 2021 : 1325 - 1332
  • [10] Effect of Carbon Fraction on Stacking Fault Energy of Austenitic Stainless Steels
    Tae-Ho Lee
    Heon-Young Ha
    Byoungchul Hwang
    Sung-Joon Kim
    Eunjoo Shin
    Metallurgical and Materials Transactions A, 2012, 43 : 4455 - 4459
12345