Title :
Analysis of anisotropic high temperature superconductor planar structures on sapphire anisotropic substrates
Author :
Megahed, Mohamed A. ; El-Ghazaly, Samir M.
Author_Institution :
Dept. of Electr. Eng., Arizona State Univ., Tempe, AZ, USA
fDate :
8/1/1995 12:00:00 AM
Abstract :
A full-wave finite-difference time-domain technique is used to study the anisotropy associated with high temperature superconductor (HTS) planar structures. The analysis is performed on anisotropic YBCO film deposited on anisotropic sapphire substrate. The solution incorporates all the physical aspects of the HTS materials. The finite thickness of the anisotropic strip is rigorously modeled using a graded non uniform mesh generator. The propagation characteristics of HTS microstrip line are evaluated. The current distributions inside the HTS are calculated for both the normal and the super fluids. It is shown that the 90° r-cut sapphire substrate structure has lower loss and lower effective dielectric constant than the 0° r-cut substrate. Interesting aspects, concerning the anisotropy of HTS microwave structures, are presented
Keywords :
barium compounds; current distribution; finite difference time-domain analysis; high-temperature superconductors; microstrip lines; sapphire; superconducting microwave devices; superconducting thin films; transmission line theory; yttrium compounds; 0° r-cut substrate; 90° r-cut sapphire; Al2O3; HTS materials; HTS microstrip line; HTS microwave structures; YBaCuO-Al2O3; anisotropic HTSC planar structures; anisotropic YBCO film; anisotropy; current distributions; effective dielectric constant; finite thickness; finite-difference time-domain technique; full-wave FDTD technique; graded nonuniform mesh generator; high temperature superconductor; loss; propagation characteristics; sapphire anisotropic substrates; Anisotropic magnetoresistance; Dielectric substrates; Finite difference methods; High temperature superconductors; Performance analysis; Strips; Superconducting films; Superconducting materials; Time domain analysis; Yttrium barium copper oxide;
Journal_Title :
Microwave Theory and Techniques, IEEE Transactions on
