Title :
Microwave measurements on high Tc superconducting single crystals and films
Author :
Fuller, W.W. ; Rachford, F.J. ; Lechter, W.L. ; Broussard, P.R. ; Allen, L.H. ; Claassen, J.H.
Author_Institution :
US Naval Res. Lab., Washington, DC, USA
fDate :
3/1/1989 12:00:00 AM
Abstract :
The authors have studied the microwave properties of a single crystal of ErBa2Cu3O7-x. The crystal was placed in the bottom of a rectangular TE 103 copper cavity whose resonant frequency was 9.2 GHz. The Q of the system, cavity and sample, as well as the frequency shift, was monitored as the system was cooled. Below about 50 K the measurements became limited by the copper cavity. Close to the superconducting transition, about 90 K, the real surface impedance is at least one order of magnitude higher than that calculated from Mattis and Bardeen´s (1958) formula. The authors have also studied using both resonant and nonresonant methods the microwave properties of an oriented film of YBa2Cu3O7-x grown on a MgO substrate. For both types of measurements they have studied the effects of small magnetic fields, less than 100 G, on the microwave losses at 9.2 and 10 GHz in a microwave cavity and by a nonresonant technique. The results are discussed in terms of flux entry and pinning at grain boundaries
Keywords :
barium compounds; erbium compounds; high-temperature superconductors; microwave spectra of inorganic solids; superconducting thin films; superconducting transition temperature; surface conductivity; yttrium compounds; 9.2 to 10 GHz; 90 K; ErBa2Cu3O7-x; MgO; YBa2Cu3O7-x; films; flux entry; frequency shift; grain boundaries; high Tc superconducting single crystals; high temperature superconductors; microwave losses; microwave properties; nonresonant methods; oriented film; pinning; resonant methods; single crystal; small magnetic fields; superconducting transition; surface impedance; Copper; Magnetic field measurement; Microwave measurements; Microwave theory and techniques; Monitoring; Resonant frequency; Superconducting films; Superconducting microwave devices; Surface impedance; Tellurium;
Journal_Title :
Magnetics, IEEE Transactions on
