Superconductivity in the antiperovskite Dirac-metal oxide Sr3SnO

Abstract

Oxides with perovskite-based structures have been known as essential materials for fascinating phenomena such as high-temperature and unconventional superconductivity. Discoveries of these oxide superconductors have driven the science community to vastly extend the concepts of strongly correlated electron systems. The base of these materials, the cubic perovskite oxides, ABO3, also exhibit superconductivity with Tc of up to 30 K, as reported for Ba0.6K0.4BiO3. Perovskite oxides have their counterparts, antiperovskite oxides A3BO (or "BOA3"), in which the position of metal and oxygen ions are reversed and therefore metallic B ions take unusual negative valence states. However, no superconductivity has been reported among antiperovskite oxides. Here, we report the discovery of the first superconducting antiperovskite oxide Sr3SnO with Tc of around 5 K. Sr3SnO possesses Dirac points in its electronic structure, originating from the inversion of bands with different parities. Based on theoretical analysis, we propose possibility of topological odd-parity superconductivity analogous to the superfluid 3He-B, in moderately hole-doped Sr3SnO, originating from unusual orbital texture on the Fermi surface. We envision that this discovery of a new class of oxide superconductor with the inverted valence configuration will stimulate the exploration of topological materials science based on a variety of antiperovskite oxides.