Assessing the possible superconductivity in doped perovskite hydride KMgH3: Effects of lattice anharmonicity and spin fluctuations

Abstract

The superconducting properties of uniformly hole-doped perovskite hydride KMgH3 with varying doping concentration and lattice parameter corresponding to different pressures were investigated from first principles. The superconducting transition temperature (Tc) was predicted from the density functional theory for superconductors (SCDFT), where the effects of lattice anharmonicity and spin-fluctuation were considered and examined. Although lattice anharmonicity tends to suppress superconductivity around the edge of dynamical stability, where the phase is stabilized due to anharmonic effects, Tc is enhanced. In the hole-doped KMgH3, substantial spin-fluctuation (SF) effects were discovered, which counters the phonon-mediated pairing and decreases Tc. Such anomalously strong SF is evaluated for similar hydrides, where the hydrogen 1-s bands are isolated at the Fermi level, and its correlation with the electronics density of states was explored.

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