Novel Electronic Structure of Nitrogen-Doped Lutetium Hydrides

Abstract

First-principles density functional theory (DFT) calculations of Lu-H-N compounds reveal low-energy configurations of Fm3m Lu8H23-xN structures that exhibit novel electronic properties such as flat bands, sharply peaked densities of states (van Hove singularities, vHs), and intersecting Dirac cones near the Fermi energy (EF). These N-doped LuH3-based structures also exhibit an interconnected metallic hydrogen network, which is a common feature of high-Tc hydride superconductors. Electronic property systematics give estimates of Tc for optimally ordered structures that are well above the critical temperatures predicted for structures considered previously. The vHs and flat bands near EF are enhanced in DFT+U calculations, implying strong correlation physics should also be considered for first-principles studies of these materials. These results provide a basis for understanding the novel electronic properties observed for nitrogen-doped lutetium hydride.