Title :
Open resonator mode patterns for characterization of anisotropic dielectric substrates for HTS thin films
Author :
Harrington, T.E. ; Wosik, J. ; Long, S.A.
Author_Institution :
Texas Center for Supercond., Houston Univ., TX, USA
fDate :
6/1/1997 12:00:00 AM
Abstract :
An open resonator possesses a unique combination of advantages for characterizing the millimeter-wave losses of today´s best HTS thin films and substrates. One of the primary advantages is the transverse linearly-polarized electric field of the TEM/sub 00q/ modes, which induces a polarized current in any HTS, dielectric, or semiconductor sample placed inside the resonator. The polarized current flow allows detection and quantification of any material anisotropies. To provide an intuitive understanding of the field and current distributions in an open resonator, mode patterns computed with a finite-difference time-domain model are presented. The theory of open-resonator anisotropic-dielectric testing is reviewed, and measured anisotropic dielectric constants of sapphire, LaAlO/sub 3/, and NdGaO/sub 3/ substrates are listed.
Keywords :
Fabry-Perot resonators; cavity resonators; current distribution; dielectric materials; finite difference time-domain analysis; high-temperature superconductors; lanthanum compounds; millimetre wave measurement; permittivity measurement; sapphire; sodium compounds; substrates; superconducting thin films; Al/sub 2/O/sub 3/; HTS thin films; LaAlO/sub 3/; LaAlO/sub 3/ substrate; NdGaO/sub 3/; NdGaO/sub 3/ substrate; TEM/sub 00q/ modes; anisotropic dielectric constants; anisotropic dielectric substrates; current distribution; dielectric constant measurements; field; finite-difference time-domain model; material anisotropies; millimeter-wave losses; mode patterns; open resonator mode patterns; open-resonator anisotropic-dielectric testing; polarized current; polarized current flow; sapphire substrate; transverse linearly-polarized electric field; Anisotropic magnetoresistance; Current distribution; Dielectric materials; Dielectric substrates; Dielectric thin films; Distributed computing; High temperature superconductors; Polarization; Semiconductor materials; Semiconductor thin films;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
