Electride States and Superconductivity in Dense Potassium Carbides

Abstract

Metal carbides have attracted a great deal of attention due to their diverse geometric motifs, remarkable physicochemical properties, and widespread practical applications. However, there is still a lack of systematic understanding regarding the phase diagram of pressurized potassium carbide. Employing first-principles swarm-intelligence structure prediction approach, we comprehensively explore the binary potassium-carbon phases under compression and identify a series of new K-rich and C-rich stoichiometric compounds. Among them, K7C with high K concentration manifests a monoclinic structure with space group C2/m and is predicted to be an electride with zero-dimensional (0D) interstitial electrons. C-abundant KC has an orthorhombic configuration with symmetry Imma, with the carbon atoms arranged in a zigzag pattern. Strikingly, KC3, belonging to a monoclinic C2/m structure, possesses the highest carbon content and features a crumpled honeycomb carbon layer. Furthermore, calculations of electron-phonon coupling reveals that K7C is a 0D electride superconductor with a transition temperature (Tc) of 0.6 K at a pressure of 25 GPa. By contrast, KC exhibits a maximum Tc of 21.4 K at 25 GPa, which is primarily attributed to the robust coupling between low-frequency K- and C-derived phonon modes and C 2p electrons at the Fermi level. In addition, KC3 is calculated to have a Tc value of 6.7 K at 25 GPa. This study provides valuable insights into K-C compounds and broadens the diversity of metal carbide superconductors.