Screening in a two-band model for superconducting infinite-layer nickelate

Abstract

Starting from an effective two-dimensional two-band model for infinite layered nickelates, consisting of bands obtained from d and s--like orbitals, we investigate to which extend it can be mapped onto a single-band Hubbard model. We identify screening of the more itinerant s-like band as an important driver. In absence of screening one strongly-correlated band gives an antiferromagnetic ground state. For weak screening, the strong correlations push electrons out of the s-band so that the undoped nickelate remains a Mott insulator with half filled d orbitals. This regime markedly differs from the observations in high-Tc cuprates and pairing with s-wave symmetry would rather be expected in the superconducting state. In contrast, for strong screening, the s and dx2-y2 bands are both partly filled and couple only weakly, so that one approximately finds a self-doped d band as well as tendencies towards d-wave pairing. Particularly in the regime of strong screening mapping to a one-band model gives interesting spectral weight transfers when a second s band is also partly filled. We thus find that both one-band physics and a Kondo-lattice--like regime emerge from the same two-orbital model, depending on the strength of electronic correlations and the size of the s-band pocket.