Cometal Addition Effect on Superconducting Properties and Granular Behaviours of Polycrystalline FeSesub.0.5Tesub.0.5

The enhanced performance of superconducting FeSe[sub.0.5]Te[sub.0.5] materials with added micro-sized Pb and Sn particles is presented. A series of Pb- and Sn-added FeSe[sub.0.5]Te[sub.0.5] (FeSe[sub.0.5]Te[sub.0.5] + xPb + ySn; x = y = 0-0.1) bulks are fabricated by the solid-state reaction method and characterized through various measurements. A very small amount of Sn and Pb additions (x = y ≤ 0.02) enhance the transition temperature (T[sub.c] [sup.onset]) of pure FeSe[sub.0.5]Te[sub.0.5] by ~1 K, sharpening the superconducting transition and improving the metallic nature in the normal state, whereas larger metal additions (x = y ≥ 0.03) reduce T[sub.c] [sup.onset] by broadening the superconducting transition. Microstructural analysis and transport studies suggest that at x = y > 0.02, Pb and Sn additions enhance the impurity phases, reduce the coupling between grains, and suppress the superconducting percolation, leading to a broad transition. FeSe[sub.0.5]Te[sub.0.5] samples with 2 wt% of cometal additions show the best performance with their critical current density, J[sub.c], and the pinning force, Fp, which might be attributable to providing effective flux pinning centres. Our study shows that the inclusion of a relatively small amount of Pb and Sn (x = y ≤ 0.02) works effectively for the enhancement of superconducting properties with an improvement of intergrain connections as well as better phase uniformity.