Title :
Field Angle Dependence of Critical Current Density in YGdBCO Coated Conductor
Author :
Kiuchi, M. ; Koida, T. ; Minami, J. ; Takahashi, Y. ; Otabe, E.S. ; Matsushita, T. ; Miura, M. ; Izumi, T. ; Shiohara, Y. ; Kato, T.
Author_Institution :
Fac. of Comput. Sci. & Syst. Eng., Kyushu Inst. of Technol., Iizuka, Japan
fDate :
6/1/2011 12:00:00 AM
Abstract :
The improvement of critical current density properties of REBCO coated conductors for applications in superconducting power devices is desired. It is known that the critical current density Jc of REBCO thin films made by the TFA-MOD method in a magnetic field is greatly improved by the introduction of BZO-nanoparticles of a non-superconducting phase as artificial pinning centers. In addition, the field angle anisotropy can also be reduced by isotropic flux pinning interactions of nanoparticles. However, a detailed report on the mechanism of flux pinning with a quantitative investigation in such coated conductors has not been given. In this study, the field angle dependence of the critical current density is measured for TFA-MOD-processed YGdBCO coated conductor with a superconducting layer of 0.65 μm thick, and the results are theoretically analysed to clarify the flux pinning mechanism.
Keywords :
barium compounds; coating techniques; conductors (electric); critical current density (superconductivity); flux pinning; gadolinium compounds; high-temperature superconductors; superconducting thin films; yttrium compounds; Y1-xGdxBa2Cu3OY; artificial pinning centers; coated conductor; critical current density; field angle anisotropy; isotropic flux pinning interactions; magnetic field effect; metal-organic deposition; nanoparticles; size 0.65 mum; superconducting layer; superconducting power devices; Anisotropic magnetoresistance; Conductors; Copper; Critical current density; Perpendicular magnetic anisotropy; Superconducting magnets; BZO-nanoparticle; YGdBCO coated conductor; critical current density; field angle anisotropy; flux pinning;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2010.2096373
