Electrode materials based on a Ti–Al–C MAX phase

被引:0
|
作者
A. M. Stolin
P. M. Bazhin
O. A. Averichev
M. I. Alymov
A. O. Gusev
D. A. Simakov
机构
[1] Russian Academy of Sciences,Institute of Structural Macrokinetics and Materials Science
[2] Russian Academy of Sciences,Baikov Institute of Metallurgy and Materials Science
[3] OOO Rusal Engineering and Technology Centre,undefined
来源
Inorganic Materials | 2016年 / 52卷
关键词
MAX phase; electrode material; SHS extrusion; shear deformation; combustion; synthesis; molding;
D O I
暂无
中图分类号
学科分类号
摘要
Long-length electrode materials based on Ti–Al–C MAX phases have been produced by self-propagating high-temperature synthesis (SHS) in combination with extrusion and their structure and performance parameters have been studied. The results demonstrate that, varying the composition of the starting mixture and parameters of the SHS extrusion process, one can obtain materials based on the MAX phases Ti3AlC2 and Ti2AlC and containing intermetallic and carbide inclusions or free of carbide components. Using the SHS extrusion process, we have produced MAX phase-based rods up to 10 mm in diameter and 350 mm in length, ranging in porosity from 2 to 16%.
引用
收藏
页码:998 / 1001
页数:3
相关论文
共 50 条
  • [21] Preparation and properties of Ti-Al-Ti laminated composite electrode materials
    Yang, Xiu-Qin
    Zhu, Pei-Xian
    Huang, Wen-Fang
    Zhou, Sheng-Gang
    Xu, Jian
    Zhang, Jin
    Ma, Hui-Yu
    Cailiao Rechuli Xuebao/Transactions of Materials and Heat Treatment, 2010, 31 (08): : 15 - 19
  • [22] Cocrystallization of Max-Phases in the Ti–Al–C System
    S. V. Sleptsov
    A. A. Bondar
    V. T. Witusiewicz
    U. Hecht
    B. Hallstedt
    V. M. Petyukh
    O. I. Dovbenko
    T. Ya. Velikanova
    Powder Metallurgy and Metal Ceramics, 2015, 54 : 471 - 481
  • [23] Materials based on the MAX phases of the Ti-Al-C system obtained under combustion and high-temperature shear deformation
    Bazhina, A. D.
    Konstantinov, A. S.
    Chizhikov, A. P.
    Avdeeva, V. V.
    Bazhin, P. M.
    MATERIALS LETTERS, 2022, 318
  • [24] Synthesis and Oxidation Testing of MAX Phase Composites in the Cr-Ti-Al-C Quaternary System
    Horlait, Denis
    Grasso, Salvatore
    Al Nasiri, Nasrin
    Burr, Patrick A.
    Lee, William Edward
    JOURNAL OF THE AMERICAN CERAMIC SOCIETY, 2016, 99 (02) : 682 - 690
  • [25] Mechanochemical synthesis mechanism of Ti3AlC2 MAX phase from elemental powders of Ti, Al and C
    Shahin, N.
    Kazemi, Sh.
    Heidarpour, A.
    ADVANCED POWDER TECHNOLOGY, 2016, 27 (04) : 1775 - 1780
  • [26] Formation of Ti 3 AlC 2 MAX phase in the Ti -Al -C system with B 2 O 3 additive
    Rud, Alexander
    Kirian, Inna
    Zagorodniy, Yuriy
    Trachevski, Vladimir
    Skoryk, Mykola
    Lakhnik, Andrey
    Voynash, Victor
    OPEN CERAMICS, 2024, 18
  • [27] Heat treatment of composite based on MAX-phases of the Ti-Al-C system
    Galyshev, Sergey
    Bazhin, Pavel
    Stolin, Alexander
    Musin, Fanil
    Astanin, Vasiliy
    INTERNATIONAL CONFERENCE ON MODERN TRENDS IN MANUFACTURING TECHNOLOGIES AND EQUIPMENT (ICMTMTE 2017), 2017, 129
  • [28] Ti–Al–C MAX Phases and Ti–C MXenes via SHS Route and Acid Leaching
    A. M. Shulpekov
    O. K. Lepakova
    V. D. Kitler
    N. N. Golobokov
    N. I. Afanas’ev
    International Journal of Self-Propagating High-Temperature Synthesis, 2021, 30 : 159 - 164
  • [29] Formation of the structure and phase composition of the Ti-Al-Ta-based materials
    Kamynina, O. K.
    Bozhko, S. A.
    Boyarchenko, O. D.
    Vadchenko, S. G.
    Sychev, A. E.
    Umarov, L. M.
    Sachkova, N. V.
    Golosov, E. V.
    Goryainov, A. A.
    RUSSIAN JOURNAL OF NON-FERROUS METALS, 2016, 57 (05) : 489 - 496
  • [30] Formation of the structure and phase composition of the Ti–Al–Ta-based materials
    O. K. Kamynina
    S. A. Bozhko
    O. D. Boyarchenko
    S. G. Vadchenko
    A. E. Sychev
    L. M. Umarov
    N. V. Sachkova
    E. V. Golosov
    A. A. Goryainov
    Russian Journal of Non-Ferrous Metals, 2016, 57 : 489 - 496
12345