Critical Current Distributions of Recent Bi-2212 Round Wires

Abstract

Bi-2212 is the only high-field, high-temperature superconductor (HTS) capable of reaching a critical current density Jc(16 T, 4.2 K) of 6500 A· mm-2 in the highly desirable round wire (RW) form. However, state-of-the-art Bi-2212 conductors still have a critical current density (Jc) to depairing current density (Jd) ratio around 20 to 30 times lower than that of state-of-the-art Nb-Ti or REBCO. Previously, we have shown that recent improvements in Bi-2212 RW Jc are due to improved connectivity associated with optimization of the heat treatment process, and most recently due to a transition to a finer and more uniform powder manufactured by Engi-Mat. One quantitative measure of connectivity may be the critical current (Ic) distribution, since the local Ic in a wire can vary along the length due to variable vortex-microstructure interactions and to factors such as filament shape variations, grain-to-grain connectivity variations and blocking secondary phase distributions. Here we compare 0.1 m length Ic distributions of Bi-2212 RWs with recent state-of-the-art very high-Jc Engi-Mat powder and lower Jc and older Nexans granulate powder. We do find that the Ic spread for Bi-2212 wires is about twice the relative standard of high-Jc Nb-Ti well below Hirr. We do not yet see any obvious contribution of the Bi-2212 anisotropy to the Ic distribution and are rather encouraged that these Bi-2212 round wires show relative Ic distributions not too far from high-Jc Nb-Ti wires.