General Trends of Structure Formation in Graded Composite Materials Based on the Ti3AlC2 MAX Phase on Titanium

被引:0
|
作者
A. D. Prokopets
A. S. Konstantinov
A. P. Chizhikov
P. M. Bazhin
A. M. Stolin
机构
[1] Merzhanov Institute of Structural Macrokinetics and Materials Science,
[2] Russian Academy of Sciences,undefined
来源
Inorganic Materials | 2020年 / 56卷
关键词
graded composite material; unconfined self-propagating high-temperature synthesis compaction; MAX phase; synthesis; structure;
D O I
暂无
中图分类号
学科分类号
摘要
引用
收藏
页码:1087 / 1091
页数:4
相关论文
共 50 条
  • [21] Electrical and thermal conductivity of the Ti3AlC2 MAX phase at low temperatures
    Khadzhai, G. Ya.
    Vovk, R. V.
    Prichna, T. A.
    Gevorkyan, E. S.
    Kislitsa, M. V.
    Solovjov, A. L.
    LOW TEMPERATURE PHYSICS, 2018, 44 (05) : 451 - 452
  • [22] Preparation and characteristics of Ti3AlC2 -Al3Ti/Al composite materials synthesized from pure Al and Ti3AlC2 powders
    Wang, Yuanbo
    Huang, Zhenying
    Hu, Wenqiang
    Cai, Leping
    Lei, Cong
    Yu, Qun
    Jiao, Yidan
    MATERIALS CHARACTERIZATION, 2021, 178
  • [23] Molten salt synthesis and formation mechanism of Ti3AlC2: A new path from Ti2AlC to Ti3AlC2
    Zhong, Yi
    Liu, Ying
    Jin, Na
    Lin, Zifeng
    Ye, Jinwen
    JOURNAL OF THE AMERICAN CERAMIC SOCIETY, 2023, 106 (09) : 5567 - 5579
  • [24] Microstructural evolution and wear mechanism of Ti3AlC2 - Ti2AlC dual MAX phase composite consolidated by spark plasma sintering (SPS)
    Magnus, Carl
    Cooper, Daniel
    Sharp, Joanne
    Rainforth, William M.
    WEAR, 2019, 438
  • [25] Structure, morphology and electrical transport properties of the Ti3AlC2 materials
    Goc, K.
    Prendota, W.
    Chlubny, L.
    Straczek, T.
    Tokarz, W.
    Borowiak , P.
    Witulska , K.
    Bucko, M. M.
    Przewoinik, J.
    Lis, J.
    CERAMICS INTERNATIONAL, 2018, 44 (15) : 18322 - 18328
  • [26] The study of homogeneity of the hexagonal Ti3AlC2 phase with inclusions of the titanium carbide
    Grib, A.
    Petrushenko, S.
    Dukarov, S.
    Prikhna, T.
    Serbenyuk, T.
    LOW TEMPERATURE PHYSICS, 2023, 49 (04) : 433 - 437
  • [27] Formation of Bulk Samples from the Ti3AlC2 MAX-Phase Powder by Selective Laser Sintering
    Krinitcyn, M. G.
    Firsina, I. A.
    Baranovskiy, A., V
    Ragulina, M. P.
    INORGANIC MATERIALS-APPLIED RESEARCH, 2022, 13 (03) : 641 - 645
  • [28] First-principles study of hydrogen incorporation into the MAX phase Ti3AlC2
    Ding, Haimin
    Glandut, Nicolas
    Fan, Xiaoliang
    Liu, Qing
    Shi, Yu
    Jie, Jinchuan
    INTERNATIONAL JOURNAL OF HYDROGEN ENERGY, 2016, 41 (15) : 6387 - 6393
  • [29] Formation of Bulk Samples from the Ti3AlC2 MAX-Phase Powder by Selective Laser Sintering
    M. G. Krinitcyn
    I. A. Firsina
    A. V. Baranovskiy
    M. P. Ragulina
    Inorganic Materials: Applied Research, 2022, 13 : 641 - 645
  • [30] The effect of Ti3AlC2 MAX phase synthetic history on the structure and electrochemical properties of resultant Ti3C2 MXenes
    von Treifeldt, Joel E.
    Firestein, Konstantin L.
    Fernando, Joseph F. S.
    Zhang, Chao
    Siriwardena, Dumindu P.
    Lewis, Courtney-Elyce M.
    Golberg, Dmitri, V
    MATERIALS & DESIGN, 2021, 199
12345