Title :
Transport critical current densities in bulk Tl2Ba2 Ca2Cu3Ox and polycrystalline-thin-film Tl2Ba2Ca1Cu 2Ox: dependence on microstructure and neut
Author :
Maley, M.P. ; Vogt, G.J. ; Phillips, D.S. ; Coulter, J.Y. ; Arendt, P.N. ; Elliot, N.E.
Author_Institution :
Los Alamos Nat. Lab., NM, USA
fDate :
3/1/1991 12:00:00 AM
Abstract :
The authors report investigations of the dependence of transport critical current density, Jc, upon magnetic field, B, at 4, 64, and 75 K in a bulk ceramic sample of Tl2Ba2 Ca2Cu3Ox and in a polycrystalline, textured thin film of Tl2Ba2CaCu 2Ox. In ceramic samples of Tl-2223, the authors generally observe the double-step Jc versus B characteristic, in which Jc drops from its zero field value to a plateau reached at B~100 Oe. The plateau region then extends to a higher field B*(T) beyond which Jc(B) decreases monotonically. Plateau Jc (75 K, 1.0 T) values>300 A/cm2 with B*(75 K)~1.5 T were achieved. In these samples, a pronounced peak effect is observed in which J c(B) increases monotonically with increasing B for 100<B(O e)<B*. After neutron irradiation, B* is observed to be significantly enhanced, suggesting that B* signals the onset of rapid flux creep. The textured polycrystalline film shows enhanced values of Jc~2×105 A/cm2 at 64 K, O T and the absence of weak-link behavior
Keywords :
barium compounds; calcium compounds; ceramics; critical current density (superconductivity); crystal microstructure; flux creep; high-temperature superconductors; neutron effects; superconducting thin films; thallium compounds; 4 K; 64 K; 75 K; Tl-2223; Tl2Ba2Ca1Cu2Ox ; Tl2Ba2Ca2Cu3Ox ; bulk; bulk ceramic sample; double-step; high temperature superconductors; magnetic field; microstructure; neutron irradiation damage; peak effect; polycrystalline-thin-film; rapid flux creep; textured thin film; transport critical current density; Ceramics; Critical current density; High temperature superconductors; Neutrons; Superconducting films; Superconducting materials; Superconducting transition temperature; Superconductivity; Temperature distribution; Transistors;
Journal_Title :
Magnetics, IEEE Transactions on
