Superconducting properties of internal-tin route Nb3Sn wires with radially arranged filaments: Development that realizes high Jc and low hysteresis loss

Abstract An internal-tin route Nb 3 Sn superconducting wire that has both remarkably low hysteresis loss ( Q h ) and high critical current density ( J c ) was developed according to a new design idea. The wire was constructed by arranging the filaments in a radial layout, enlarging the outer filaments along the radial direction, narrowing the filament spacing in the radial direction intentionally and enlarging the filament spacing in tangential direction. Thus, the electromagnetic coupling among the filaments in tangential direction due to the bridging and/or proximity effect was suppressed without decreasing the volume fraction of Nb. As a result, excellent properties such as J c (12 T) = 1.15 × 10 3  A/mm 2 and Q h  = 301 mJ/cm 3 (for 1 cycle of B  = ±3 T) were obtained. We also evaluated the transition temperature ( T c ) and upper critical field ( B c2 ) of the wire. The values for T c and B c2 were 17.3 K and 24.1 T, respectively, which were much better than those of usual internal-tin route wires. Moreover, electron probe micro-analyses confirmed that the good T c and B c2 were the result of the qualitative improvement of the Nb 3 Sn compound based on the effects of arranging the Nb filaments radially, increasing the ratio of Sn-to-Nb and shortening the diffusion length for Sn. This wire is promising for use with conduction-cooled high-field magnets, in which there is a need to decrease the load of the cryocooler, and also for the strands of fusion coils.