Grain-Boundary Diffusion of Cobalt in Submicrocrystalline Molybdenum Obtained by High-Pressure Torsion

被引:9
作者
Popov, V. V. [1 ]
Sergeev, A. V. [1 ]
机构
[1] Russian Acad Sci, Ural Branch, Mikheev Inst Met Phys, Ekaterinburg 620990, Russia
来源
PHYSICS OF METALS AND METALLOGRAPHY | 2017年 / 118卷 / 11期
基金
俄罗斯基础研究基金会;
关键词
cobalt; molybdenum; high-pressure torsion; grain-boundary diffusion; layer-by-layer radiometric analysis; SEVERE PLASTIC-DEFORMATION; EMISSION MOSSBAUER-SPECTROSCOPY; METALS; MO;
D O I
10.1134/S0031918X17110126
中图分类号
TF [冶金工业];
学科分类号
0806 ;
摘要
Radiometric layer-by-layer analysis has been used to study the grain-boundary diffusion of Co in submicrocrystalline Mo produced by severe plastic deformation using high-pressure torsion. It has been found that, under severe plastic deformation, nonequilibrium grain boundaries have been formed, which are ultrafast diffusion paths. During annealing, the recovery of nonequilibrium grain boundaries takes place. The properties of boundaries that underwent the recovery were shown to be close to those of boundaries originated by recrystallization in coarse-grained Mo. As the annealing temperature increases, the fraction of nonequilibrium boundaries decreases; and beginning from 823 K, there are no more nonequilibrium boundaries in the structure.
引用
收藏
页码:1091 / 1096
页数:6
相关论文
共 50 条
  • [31] The grain-boundary diffusion of zn in α-fe
    Dohie, Jonathan S.
    Cahoon, J. R.
    Caley, W. F.
    JOURNAL OF PHASE EQUILIBRIA AND DIFFUSION, 2007, 28 (04) : 322 - 327
  • [32] The Grain-Boundary Diffusion of Zn in α-Fe
    Jonathan S. Dohie
    J.R. Cahoon
    W.F. Caley
    Journal of Phase Equilibria and Diffusion, 2007, 28 : 322 - 327
  • [33] Determination of the parameters of grain-boundary diffusion and segregation of Co in W using an improved model of grain-boundary diffusion
    V. V. Popov
    A. V. Sergeev
    N. K. Arkhipova
    A. Yu. Istomina
    The Physics of Metals and Metallography, 2011, 112 : 256 - 266
  • [34] Grain-Boundary Diffusion of 57Co in Ultrafine Nickel after Severe Plastic Deformation
    Osinnikov, E., V
    Murzinova, S. A.
    Istomina, A. Yu
    Popov, V. V.
    Stolbovskiy, A., V
    Falahutdinov, R. M.
    PHYSICS OF METALS AND METALLOGRAPHY, 2021, 122 (10) : 976 - 980
  • [35] High strength in layered metal composites obtained by high-pressure torsion
    Rogachev, S. O.
    Khatkevich, V. M.
    Sundeev, R., V
    MATERIALS LETTERS, 2021, 303
  • [36] Fabrication of nanocomposites through diffusion bonding under high-pressure torsion
    Kawasaki, Megumi
    Han, Jae-Kyung
    Lee, Dong-Hyun
    Jang, Jae-il
    Langdon, Terence G.
    JOURNAL OF MATERIALS RESEARCH, 2018, 33 (18) : 2700 - 2710
  • [37] Thermal stability of nickel structure obtained by high-pressure torsion in liquid nitrogen
    Popov, V. V.
    Popova, E. N.
    Kuznetsov, D. D.
    Stolbovskii, A. V.
    Pilyugin, V. P.
    PHYSICS OF METALS AND METALLOGRAPHY, 2014, 115 (07) : 682 - 691
  • [38] Developing grain refinement and superplasticity in a magnesium alloy processed by high-pressure torsion
    Kai, Masaaki
    Horita, Zenji
    Langdon, Terence G.
    MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING, 2008, 488 (1-2): : 117 - 124
  • [39] Grain refinement and superplastic flow in an aluminum alloy processed by high-pressure torsion
    Dobatkin, SV
    Bastarache, EN
    Sakai, G
    Fujita, T
    Horita, Z
    Langdon, TG
    MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING, 2005, 408 (1-2): : 141 - 146
  • [40] Kinetics of Grain Growth upon the Heating of Nickel Deformed by High-Pressure Torsion
    Voronova, L. M.
    Degtyarev, M. V.
    Chashchukhina, T. I.
    PHYSICS OF METALS AND METALLOGRAPHY, 2021, 122 (06) : 559 - 565
12345