Title :
A shell model for the filament structure of Bi-2223 conductors
Author :
Holesinger, T.G. ; Kennison, J.A. ; Liao, S. ; Yuan, Y. ; Jiang, J. ; Cai, X.Y. ; Hellstrom, E.E. ; Larbalestier, D.C. ; Baurceanu, R.M. ; Maroni, V.A. ; Huang, Y.
Author_Institution :
Los Alamos Nat. Lab., NM, USA
fDate :
6/1/2005 12:00:00 AM
Abstract :
Phase development during the first few minutes of heat treatment of first generation (Bi,Pb)2Sr2Ca2Cu3Oy (Bi-2223) multifilamentary wires determines to a large extent the overall microstructure, the efficiency of primary phase development, competing secondary phase development, texture evolution, and grain-to-grain connectivity. It is shown that the filament structure of these wires can be described in terms of a shell model. The shell next to the silver sheath is comprised of well-formed Bi-2223 colonies grapho-epitaxially aligned to the silver sheath and only a few grains (average one colony) thick. Inside this shell is a less well-aligned, less phase pure, more porous Bi-2223 structure through which current is carried in a nonuniform manner as shown by MOI.
Keywords :
SQUID magnetometers; X-ray chemical analysis; bismuth compounds; calcium compounds; critical current density (superconductivity); crystal microstructure; gas mixtures; high-temperature superconductors; lead compounds; multifilamentary superconductors; scanning electron microscopy; silver; strontium compounds; superconducting tapes; transmission electron microscopy; type II superconductors; 1 to 300 mins; 5 G; 77 K; 827 C; Bi-2223 colonies; Bi-2223 conductors; Bi2PbSr2Ca2Cu3O10-Ag; Ca2PbO4; MOI; filament structure; grain-to-grain connectivity; grapho-epitaxial alignment; heat treatment; magnetic optical images; microstructure; multifilamentary wires; phase development; shell model; silver sheath; Conductors; Heat treatment; High temperature superconductors; Image reconstruction; Microstructure; Multifilamentary superconductors; Silver; Superconducting films; Superconducting transmission lines; Wires; Bi-2223; bismuth compounds; high-temperature superconductor; microscopy; processing;
Journal_Title :
Applied Superconductivity, IEEE Transactions on
DOI :
10.1109/TASC.2005.847509
