Divergent Pressure Response of Superconductivity in Sc6MTe2 (M = Fe, Ru and Ir)

Abstract

Identifying and understanding non-BCS superconductivity remains a central challenge in condensed-matter physics. Here we focus on the Sc6MTe2 family (M =d-electron metal), which provides a unique platform of isostructural compounds exhibiting superconductivity across 3d, 4d, and 5d systems. Using hydrostatic pressure as an additional tuning parameter, muon-spin rotation (μSR) and AC susceptibility measurements uncover strongly contrasting pressure responses of superconductivity across the Sc6MTe2 series. The superconducting transition temperature, T C decreases under pressure in the 3d Fe-based compound but increases for the 4d Ru- and 5d Ir-based systems, with the Ru compound showing the largest enhancement of nearly 50% within 2 GPa. The superfluid density exhibits similarly distinct pressure dependences, remaining nearly pressure independent for Fe while decreasing with increasing pressure for Ru and Ir. This suggests fundamentally different correlations between T C and the superfluid density. Together, these results indicate that superconductivity emerging from strongly correlated and spin-orbit-dominated regimes in Sc6MTe2 is likely governed by different microscopic mechanisms and offer a useful experimental basis for future microscopic theoretical studies.