Stabilization of singlet hole-doped state in infinite-layer nickelate superconductors

Abstract

Motivated by the recent X-ray absorption spectroscopy (XAS) and resonant inelastic X-ray scattering (RIXS) experiments, we use a detailed impurity model to explore the nature of the parent compound and hole doped states of (La, Nd, Pr)NiO2 by including the crystal field splitting, the Ni-3d multiplet structure, and the hybridization between Ni-3d, O-2p, and Nd-5d orbitals. For simplicity and stimulated by the recent electronic structure calculations, the latter are formally replaced with symmetric orbitals centered at the missing O sites in the Nd layer, forming a two-dimensional (2D) band strongly hybridizing with the Ni-3d9z2 state. This hybridization pushes the main part of the 3d9z2 spectral function up in energy by several eV and stabilizes the singlet with considerable d9z2 and other configurational components. For the parent compound, we find that states of Ni-3d9z2 character spread over a large energy range in the spectra, and cannot and should not be represented by a single orbital energy, as suggested in other approximations. This is qualitatively consistent with the RIXS measurements showing a broad distribution of the Ni-3d9z2 hole state, although the shape of the Ni-3d9z2 related structure is much more complicated requiring reinterpretations of the RIXS data. For the hole-doped systems, we show that adding these additional ingredients can still result in the lowest-energy hole doped state having a singlet character.