Title :
Hetero-epitaxial growth of YBCO thin films on the a-cut plane sapphire substrates
Author :
Ohshima, S. ; Shirakawa, M. ; Nishimura, T. ; Saito, A. ; Mukaida, M.
Author_Institution :
Fac. of Eng., Yamagata Univ., Yonezawa, Japan
fDate :
6/1/2005 12:00:00 AM
Abstract :
We examined the hetero-epitaxial growth of YBCO thin films on the a-cut plane sapphire substrates for the passive microwave applications, because the a-cut plane sapphire substrates have smaller in-plane anisotropy of the dielectric constant compared with that of r-cut plane sapphire substrates. The CeO2 buffer layers and YBCO thin films were prepared by an inductive-coupled plasma sputtering method. We found that perfect in-plane alignment of the CeO2 buffer layer could be obtained on the a-cut plane sapphire substrates. Also we could obtain the hetero-epitaxial YBCO thin films on CeO2/a-cut plane sapphire substrates. Tc of the YBCO thin films was approximately 89 K, and the surface resistance (Rs) of the YBCO thin films was approximately 1 mΩ at 50 K and at 22 GHz, equivalently to values for YBCO thin films fabricated on the r-cut plane sapphire substrates.
Keywords :
barium compounds; buffer layers; cerium compounds; magnetic anisotropy; sapphire; sputtering; superconducting epitaxial layers; surface resistance; yttrium compounds; 1 mohm; 22 GHz; 50 K; 89 K; Al2O3; CeO2; YBCO thin films; YBa2Cu3O7; a-cut plane sapphire substrates; buffer layers; dielectric constant; hetero-epitaxial growth; in-plane anisotropy; inductive-coupled plasma sputtering method; passive microwave application; surface resistance; Anisotropic magnetoresistance; Buffer layers; Dielectric constant; Dielectric substrates; Dielectric thin films; Plasma applications; Sputtering; Surface resistance; Transistors; Yttrium barium copper oxide; Buffer layer; Tc; YBCO; hetero-epitaxy; surface resistance;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2005.848694
