Electropulse ("Spark") Plasma Sintering of Tungsten and W+5%Ni Nanopowders Obtained by High-Energy Ball Milling

被引:0
|
作者
Lantsev, E. A. [1 ]
Malekhonova, N. V. [1 ]
Nokhrin, A. V. [1 ]
Smetanina, K. E. [1 ]
Murashov, A. A. [1 ]
Shcherbak, G. V. [1 ]
Voronin, A. V. [1 ]
Atopshev, A. A. [1 ]
机构
[1] Lobachevsky Univ Nizhny Novgorod, Nizhnii Novgorod 603105, Russia
来源
TECHNICAL PHYSICS | 2024年 / 69卷 / 05期
关键词
tungsten; mechanical activation; nanopowders; spark plasma sintering; density; grain size; diffusion; MECHANICAL-PROPERTIES; HEAVY ALLOYS; MICROSTRUCTURE;
D O I
10.1134/S1063784224040200
中图分类号
O59 [应用物理学];
学科分类号
摘要
The mechanisms of high-speed sintering of tungsten and W+5wt%Ni nanopowders obtained by high-energy ball milling (HEBM) have been studied. The phase composition, microstructure parameters, hardness and fracture resistance of the obtained samples were investigated. It is shown that the samples have high relative density, small grain size and increased hardness. It is established that the formation of strong intermetallic phases MexWyCz and MexWy, as well as MeO oxides occurs at SPS of mechanically activated nanopowders. The simultaneous increase in the content of intermetallic phases and reduction of the grain size leads to a non-monotone character of the dependence of the SPS activation energy on the HEBM time. It is shown that the main mechanism of SPS of tungsten W+5wt%Ni nanopowders is Coble creep.
引用
收藏
页码:1249 / 1258
页数:10
相关论文
共 50 条
  • [21] Production of a Reinforced Refractory Multielement Alloy via High-Energy Ball Milling and Spark Plasma Sintering
    Menapace, Cinzia
    Shaik, Khaja Naib Rasool
    Emanuelli, Lorena
    Ischia, Gloria
    METALS, 2023, 13 (07)
  • [22] Preparation of WC/MgO composite nanopowders by high-energy reactive ball milling and their plasma-activated sintering
    Zhang, Meilin
    Zhu, Shigen
    Jun, Ma
    Wu, Caixia
    POWDER METALLURGY AND METAL CERAMICS, 2008, 47 (9-10) : 525 - 530
  • [23] Preparation of WC/MgO composite nanopowders by high-energy reactive ball milling and their plasma-activated sintering
    Meilin Zhang
    Shigen Zhu
    Ma Jun
    Caixia Wu
    Powder Metallurgy and Metal Ceramics, 2008, 47 : 525 - 530
  • [24] Nanostructured Gradient Material Based on the Cu-Cr-W Pseudoalloy Fabricated by High-Energy Ball Milling and Spark Plasma Sintering
    Shkodich, N. F.
    Vergunova, Yu. S.
    Kuskov, K. V.
    Trusov, G. V.
    Kovalev, I. D.
    RUSSIAN JOURNAL OF NON-FERROUS METALS, 2020, 61 (03) : 309 - 318
  • [25] Structure property relationship in a bulk Cu-Cr-W composite synthesized by high-energy ball milling and spark plasma sintering
    Chakraborty, S.
    Bagala, R.
    Sikdar, K.
    Roy, D.
    Basumallick, A.
    MATERIALS CHEMISTRY AND PHYSICS, 2020, 256
  • [26] Synthesis of YB2C2 by high-energy ball milling and reactive spark plasma sintering
    Nguyen, Van-Quyet
    Kim, Jun-Seop
    Lee, Sea-Hoon
    JOURNAL OF THE AMERICAN CERAMIC SOCIETY, 2021, 104 (03) : 1229 - 1236
  • [27] Development of Fe-9Cr Alloy via High-Energy Ball Milling and Spark Plasma Sintering
    Arnab Kundu
    Anumat Sittiho
    Indrajit Charit
    Brian Jaques
    Chao Jiang
    JOM, 2019, 71 : 2846 - 2855
  • [28] Effects of high-energy ball milling and reactive spark plasma sintering on the densification of HfC-SiC composites
    Feng, Lun
    Lee, Sea-Hoon
    Kim, Ha-Nul
    JOURNAL OF THE EUROPEAN CERAMIC SOCIETY, 2017, 37 (05) : 1891 - 1898
  • [29] TiC-based cermet prepared by high-energy ball-milling and reactive spark plasma sintering
    Jam, Alireza
    Nikzad, Leila
    Razavi, Mansour
    CERAMICS INTERNATIONAL, 2017, 43 (02) : 2448 - 2455
  • [30] Development of Fe-9Cr Alloy via High-Energy Ball Milling and Spark Plasma Sintering
    Kundu, Arnab
    Sittiho, Anumat
    Charit, Indrajit
    Jaques, Brian
    Jiang, Chao
    JOM, 2019, 71 (08) : 2846 - 2855
12345