Anomalous charge and negative-charge-transfer insulating state in cuprate chain-compound KCuO2

Abstract

Using a combination of X-ray absorption spectroscopy experiments with first principle calculations, we demonstrate that insulating KCuO2 contains Cu in an unusually-high formal-3+ valence state, the ligand-to-metal (O to Cu) charge transfer energy is intriguingly negative (Delta~ -1.5 eV) and has a dominant (~60%) ligand-hole character in the ground state akin to the high Tc cuprate Zhang-Rice state. Unlike most other formal Cu3+ compounds, the Cu 2p XAS spectra of KCuO2 exhibits pronounced 3d8 (Cu3+) multiplet structures, which accounts for ~40% of its ground state wave-function. Ab-initio calculations elucidate the origin of the band-gap in KCuO2 as arising primarily from strong intra-cluster Cu 3d - O 2p hybridizations (tpd); the value of the band-gap decreases with reduced value of tpd. Further, unlike conventional negative charge-transfer insulators, the band-gap in KCuO2 persists even for vanishing values of Coulomb repulsion U, underscoring the importance of single-particle band-structure effects connected to the one-dimensional nature of the compound.