Critical Currents of Bismuth 1G Tape

被引:7
|
作者
Woch, W. M. [1 ]
Zalecki, R. [1 ]
Chrobak, M. [1 ]
Kolodziejczyk, A. [1 ]
机构
[1] AGH Univ Sci & Technol, Fac Phys & Appl Comp Sci, Dept Solid State Phys, PL-30059 Krakow, Poland
来源
ACTA PHYSICA POLONICA A | 2015年 / 127卷 / 02期
关键词
SUPERCONDUCTORS;
D O I
10.12693/APhysPolA.127.315
中图分类号
O4 [物理学];
学科分类号
0702 ;
摘要
The critical currents of commercial bismuth based superconducting tape were determined in the two ways. In the first one the transport critical current density was measured by the four points method using the dc current power supply at the liquid nitrogen temperature. In the second one the critical current densities were obtained from the absorption part of ac susceptibility measurements using the Bean model near the critical temperature. The temperature dependence of the critical current densities was fitted to take advantage of the Ginzburg-Landau strong-coupling limit approach. Using the fit parameters the critical current density at 77 K was calculated. The critical temperature of this tape (T-c, = 110.5 K) was determined from the ac susceptibility measurements.
引用
收藏
页码:315 / 317
页数:3
相关论文
共 50 条
  • [21] 500MHz追1G
    个人电脑, 2000, (11) : 12 - 14
  • [22] Multichannel approach for the analysis of 1g O
    Carbone, D.
    Agodi, C.
    Bellone, J. I.
    Burrello, S.
    Cappuzzello, F.
    Cavallaro, M.
    Colonna, M.
    De Gregorio, G.
    Ferreira, J. L.
    Gargano, A.
    Lenske, H.
    Sgouros, O.
    Spatafora, A.
    Acosta, L.
    Amador-Valenzuela, P.
    Brischetto, G. A.
    Calvo, D.
    Lomeli, E. R. Chavez
    Ciraldo, I.
    DeLaunay, F.
    Djapo, H.
    Eke, C.
    Finocchiaro, P.
    Firat, S.
    Fisichella, M.
    Guazzelli, M. A.
    Hacisalihoglu, A.
    Lay, J. A.
    Linares, R.
    Lubian, J.
    Medina, N. H.
    Moralles, M.
    Oliveira, J. R. B.
    Pakou, A.
    Pandola, L.
    Petrascu, H.
    Solakci, S. O.
    Soukeras, V.
    Souliotis, G.
    Torresi, D.
    Tudisco, S.
    Yildirim, A.
    Zagatto, V. A. B.
    NUOVO CIMENTO C-COLLOQUIA AND COMMUNICATIONS IN PHYSICS, 2024, 47 (06):
  • [23] Direct calculation of the two-photon line strength of a Gamma(1g)-Gamma 1g transition in octahedral symmetry
    Chua, M
    Tanner, PA
    PHYSICAL REVIEW B, 1996, 54 (16): : 11014 - 11017
  • [24] Toward 1G Mobile Power Networks
    Clerckx, Bruno
    Costanzo, Alessandra
    Georgiadis, Apostolos
    Carvalho, Nuno Borges
    IEEE MICROWAVE MAGAZINE, 2018, 19 (06) : 69 - 82
  • [25] 鑫旺1G系列旋耕机
    农业机械, 2010, (03) : 91 - 91
  • [26] Determination of the angular dependence of the critical current Ic in high-temperature superconducting tapes 1G
    Habelok, Krzysztof
    Gruszczyk, Kamil
    Lasek, Pawel
    Stepien, Mariusz
    PRZEGLAD ELEKTROTECHNICZNY, 2024, 100 (10): : 35 - 38
  • [27] Forced piston effect experiments under 1g and μg at various densities around the critical point of SF6
    Bartscher, C
    Straub, J
    MICROGRAVITY FLUID PHYSICS AND HEAT TRANSFER, 2000, : 37 - 45
  • [28] E-1-/2G]-A-1-/1G TRANSITION IN BENZENE
    TALEB, AM
    MUNRO, IH
    BIRKS, JB
    CHEMICAL PHYSICS LETTERS, 1973, 21 (03) : 454 - 457
  • [29] ISOPYCNIC FOCUSING AT 1G AND IN MICROGRAVITY - PRINCIPLE AND INSTRUMENTATION
    JANCA, J
    INSTRUMENTATION SCIENCE & TECHNOLOGY, 1995, 23 (01) : 43 - 47
  • [30] Phenol degradation by Rhodococcus opacus strain 1G
    Shumkova, E. S.
    Solyanikova, I. P.
    Plotnikova, E. G.
    Golovleva, L. A.
    APPLIED BIOCHEMISTRY AND MICROBIOLOGY, 2009, 45 (01) : 43 - 49
12345