Induction of superconductivity by sulphur doping in FeTe system and post effect of low temperature oxygen annealing

TL;DR

This study demonstrates that sulphur doping induces superconductivity in FeTe, with low temperature oxygen annealing further enhancing the superconducting volume fraction, supported by comprehensive structural and physical property analyses.

Contribution

It introduces sulphur doping in FeTe to induce superconductivity and explores the effect of low temperature oxygen annealing on enhancing superconducting properties.

Findings

Superconductivity appears at ~8 K in S-doped FeTe.

Oxygen annealing increases superconducting volume fraction.

Lattice constants decrease with S doping.

Abstract

Here, we report the synthesis and characterization of sulphur-substituted iron telluride i.e. FeTe1-xSx; (x = 0-30 %) system and study the impact of low temperature oxygen (O2) annealing as well. Rietveld analysis of room temperature x-ray diffraction (XRD) patterns shows that all the compounds are crystallized in a tetragonal structure (space group P4/nmm) and no secondary phases are observed. Lattice constants are decreased with increasing S concentration. The parent compound of the system i.e. FeTe does not exhibit superconductivity but shows an anomaly in the resistivity measurement at around 78 K, which corresponds to a structural phase transition. Heat capacity Cp(T) measurement also confirms the structural phase transition of FeTe compound. Superconductivity appears by S substitution; the onset of superconducting transition temperature is about 8 K for FeTe0.75S0.25 sample. Thermoelectric power measurements S(T) also shows the superconducting transition at around 7 K for FeTe0.75S0.25 sample. The upper critical fields Hc2(10%), Hc2(50%) and Hc2(90%) are estimated to be 400, 650 and 900 kOe respectively at 0 K by applying Ginzburg Landau (GL) equation. Interestingly, superconducting volume fraction is increased with low temperature (200 oC) O2 annealing at normal pressure. Detailed investigations related to structural (XRD), transport [S(T), R(T)H], magnetization (AC and DC susceptibility) and thermal [Cp(T)] measurements for FeTe1-xS:O2 system are presented and discussed.