Tailoring the normal and superconducting state properties of ternary scandium tellurides, Sc$_6M$Te$_2$ ($M = $ Fe, Ru and Ir) through chemical substitution

TL;DR

This study systematically investigates the normal and superconducting properties of ternary scandium tellurides with different d-electron metals, revealing their unconventional superconductivity influenced by electron correlations and spin-orbit coupling.

Contribution

It provides new microscopic insights into the superconducting mechanisms of Sc$_6M$Te$_2$ compounds using advanced experimental techniques.

Findings

Dilute superfluid densities correlate with $T_c$

High-temperature normal-state transitions inversely relate to $T_c$

Superconducting gaps are nodeless and vary with metal substitution

Abstract

The pursuit of a unifying theory for non-BCS superconductivity has faced significant challenges. One approach to overcome such challenges is to perform systematic investigations into superconductors containing \textit{d}-electron metals in order to elucidate their underlying mechanisms. Recently, the Sc$_6M$Te$_2$ ($M$ = d-electron metal) family has emerged as a unique series of isostructural compounds exhibiting superconductivity across a range of $3d$, $4d$, and $5d$ electron systems. In this study, we employ muon spin rotation, neutron diffraction, and magnetisation techniques to probe the normal and superconducting states at a microscopic level. Our findings reveal extremely dilute superfluid densities that correlate with the critical temperature ($T_\mathrm{c}$). Additionally, we identify high-temperature normal-state transitions that are inversely correlated with $T_\mathrm{c}$. Notably, in Sc$_6$FeTe$_2$, the superconducting pairing symmetry is most likely characterised by two nodeless gaps, one of which closes as electron correlations diminish in the Ru and Ir Sc$_6M$Te$_2$ compounds. These results classify the Sc$_6M$Te$_2$ compounds ($M$ = Fe, Ru, Ir) as unconventional bulk superconductors, where the normal-state transitions and superconducting properties are governed by the interplay between electron correlations and spin-orbit coupling of the d-electron metal.