Influence of microstructure on the flux pinning in Nb-Ti multifilamentary superconducting wires

Abstract

The microstructure of multifilamentary Nb—46·5 wt% Ti composites has been investigated by means of small-angle neutron scattering measurements. The scattering intensity was analysed by assuming that the shape of α-precipitates is a flat ellipse. The volume fraction V_f of α precipitates increased from 1·3 to 13·4% as a function of the degree of thermomechanical treatment and the average thickness of precipitates changed from 1·5 to 4 nm. The superconducting critical current density for the wires examined here exceeded 3000 A mm⁻² at 5 T. The global pinning force density F_p, could be expressed as a function of the volume fraction of precipitates as F_p = F_p(0) + kV_f ^2/3, where k is a constant. The factor F_p(0) indicates the contribution from the substructure formed by heavy plastic deformation. The magnitude of F_p at high magnetic fields was found to be decreased remarkably by the final heat treatment. We attribute this effect to the recovery of the substructure.