Enhancement of superconductivity on thin film of Sn under high pressure

Abstract

We investigated the pressure effects of a superconductivity on thin films of Sn. Elemental superconductor Sn with a body-centered tetragonal structure, β-Sn, exhibits superconductivity below the superconducting transition temperature (T c=3.72 K) at ambient pressure. T c of Sn increases with lowering dimension such as in thin film and nanowire growth, or by high-pressure application. For thin films, T c exhibits a slight increase up to approximately 4 K compared to the bulk value, attributable to the crystalline size and lattice disorder. By applying pressure on a bulk Sn, T c initially decreases from 3.72 K as the pressure increases. Further increasing pressure up to 10 GPa, T c increases to 5.3 K with the structural transformation. However, the combination of these effects on thin films of Sn, namely, thin-film growth and pressure effects, remains underexplored. In this study, we combined film-growth and pressure-application techniques to further increase T c using a diamond anvil cell with boron-doped diamond electrodes. The drop of the electrical resistance suggesting the onset of T c on the thin film reached above 6 K in γ-Sn phase. Further, the upper critical magnetic field was drastically enhanced. Atomic force microscopy suggests that the refinement of the grain size of the thin film under the non-hydrostatic pressure conditions contributes to stabilizing the higher T c of γ-Sn.