Effect of low electrical potentials on the microhardness of metallic materials

被引:0
|
作者
D. V. Orlova
V. I. Danilov
L. B. Zuev
O. S. Staskevich
机构
[1] Russian Academy of Sciences,Institute of Strength Physics and Materials Science, Siberian Branch
[2] National Research Tomsk Polytechnic University,undefined
[3] National Research Tomsk State University,undefined
来源
Physics of the Solid State | 2016年 / 58卷
关键词
Zirconium; Electrical Potential; Hall Coefficient; Silicon Iron; E110 Alloy;
D O I
暂无
中图分类号
学科分类号
摘要
The effect of low (<5 V) electrical potentials on the microhardness of metallic materials has been studied experimentally. It has been revealed that this effect does depend on the sign of the electric field potential. It has been found that the microhardness of aluminum, cobalt, and zinc decreases and the microhardness of zirconium and iron increases when an electrical potential is applied. It has been argued that the degree of microhardness change under an electric field depends on the magnitude of applied potential, the magnitude of the Hall coefficient of a metal, and its physicochemical properties.
引用
收藏
页码:9 / 11
页数:2
相关论文
共 50 条
  • [1] Effect of low electrical potentials on the microhardness of metallic materials
    Orlova, D. V.
    Danilov, V. I.
    Zuev, L. B.
    Staskevich, O. S.
    PHYSICS OF THE SOLID STATE, 2016, 58 (01) : 9 - 11
  • [2] Effect of the Loading Rate on the Microhardness of Metallic Materials and the Micromechanism of Plastic Strain
    A. I. Gnevko
    N. A. Kazakov
    D. V. Lazarev
    V. V. Velichkovskii
    Metal Science and Heat Treatment, 2002, 44 : 448 - 448
  • [3] Effect of the loading rate on the microhardness of metallic materials and the micromechanism of plastic strain
    Gnevko, AI
    Kazakov, NA
    Lazarev, DV
    Velichkovskii, VV
    METAL SCIENCE AND HEAT TREATMENT, 2002, 44 (9-10) : 448 - 448
  • [4] Metallic electrical resistance materials
    Schulze, A
    ZEITSCHRIFT DES VEREINES DEUTSCHER INGENIEURE, 1933, 77 : 856 - 858
  • [5] Microhardness and abrasive wear resistance of metallic glasses and nanostructured composite materials
    Gloriant, T
    JOURNAL OF NON-CRYSTALLINE SOLIDS, 2003, 316 (01) : 96 - 103
  • [6] Considerations in measuring the electrical potentials of metallic restorations in vivo
    Sutow, EJ
    Maillet, WA
    Taylor, JC
    Hanrahan, KL
    Hall, GC
    Harandi, K
    JOURNAL OF ORAL REHABILITATION, 2000, 27 (11) : 927 - 934
  • [7] Effect of Bleaching on Microhardness of Esthetic Restorative Materials
    Malkondu, O.
    Yurdaguven, H.
    Say, E. C.
    Kazazoglu, E.
    Soyman, M.
    OPERATIVE DENTISTRY, 2011, 36 (02) : 177 - 186
  • [8] ELECTRICAL DISCHARGE (EDM) AND MACHINABILITY OF METALLIC MATERIALS BY ELECTRICAL DISCHARGE
    Uliuliuc, Dumitru
    Radeanu, Alexandru
    Boca, Mihai
    MODTECH 2010: NEW FACE OF TMCR, PROCEEDINGS, 2010, : 655 - 658
  • [9] The effect of specimen geometry on the low cycle fatigue life of metallic materials
    Bae, Keun-Ho
    Lee, Soon-Bok
    MATERIALS AT HIGH TEMPERATURES, 2011, 28 (01) : 33 - 39
  • [10] Laser and electrical breakdown damages on metallic materials
    Sreckovic, M
    Zeravic, VS
    Osmokrovic, P
    Vedlin, B
    LASER PHYSICS, 1998, 8 (06) : 1177 - 1181
12345