Superconductivity in Scandium Borocarbide with orbital hybridization
Abstract
Exploration of superconductivity in light element compounds has drawn considerable attention because those materials can easily realize the high Tc superconductivity, such as LnNi2B2C (Tc =17 K), MgB2 (Tc =39 K), and very recently super-hydrides under pressure (Tc =250 K). Here we report the discovery of bulk superconductivity at 7.8 K in scandium borocarbide Sc20BC27 with a tetragonal lattice which structure changes based on the compound of Sc3C4 with very little B doping. Magnetization and specific heat measurements show bulk superconductivity. An upper critical field of Hc2(0) ~ 8 T is determined. Low temperature specific-heat shows that this system is a BCS fully gapped s-wave superconductor. Electronic structure calculations demonstrate that compared with Sc3C4 there are more orbital overlap and hybridization between Sc 3d electrons and 2p electrons of C-C(B)-C fragment in Sc20BC27, which form a new electric conduction path of Sc-C(B)-Sc. Those changes influence the band structure at the Fermi level and may be the reason of superconductivity in Sc20BC27.
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