Prediction of High-Tc conventional Superconductivity in the Ternary Lithium Borohydride System

Abstract

We investigate the superconducting ternary lithium borohydride phase diagram at pressures of 0 and 200\,GPa using methods for evolutionary crystal structure prediction and linear-response calculations for the electron-phonon coupling. Our calculations show that the ground state phase at ambient pressure, LiBH4, stays in the Pnma space group and remains a wide band-gap insulator at all pressures investigated. Other phases along the 1:1:x Li:B:H line are also insulating. However, a full search of the ternary phase diagram at 200\,GPa revealed a metallic Li2BH6 phase, which is thermodynamically stable down to 100\,GPa. This superhydride phase, crystallizing in a Fm3m space group, is characterized by six-fold hydrogen-coordinated boron atoms occupying the fcc sites of the unit cell. Due to strong hydrogen-boron bonding this phase displays a critical temperature of 100\,K between 100 and 200\,GPa. Our investigations confirm that ternary compounds used in hydrogen-storage applications are a suitable choice for observing high-Tc conventional superconductivity in diamond anvil cell experiments, and suggest a viable route to optimize the critical temperature of high-pressure hydrides.