Prediction of phonon-mediated high temperature superconductivity in stoichiometric Li2B3C

Abstract

The discovery of superconductivity in Magnesium Diborate (MgB2) has stimulated great interest in the search of new superconductors with similar lattice structures. Unlike cuprate or iron-based superconductors, MgB2 is indisputably a phonon-mediated high temperature superconductor. The emergence of high temperature superconductivity in this material results from the strong coupling between the boron σ-bonding electrons around the Fermi level and the bond-stretching optical phonon modes. Here we show, based on the first-principles calculations, that Li2B3C is such a good candidate of superconductor whose superconducting transition temperature (Tc) might be even higher than MgB2. Li2B3C consists of alternating graphene-like boron-carbon layers and boron-boron layers with intercalated lithium atoms between them. Similar to MgB2, Li2B3C is inherently metallic and possesses two σ- and two π-electron bands around the Fermi energy. The superconducting pairs are glued predominately by the strong interaction between boron σ-bonding electrons and various optical phonon modes.