Interplay between Zhang-Rice singlets and high-spin states in a model for doped NiO2 planes

Abstract

Superconductivity found in doped NdNiO2 is puzzling as two local symmetries of doped NiO2 layers compete, with presumably far-reaching implications for the involved mechanism: a cuprate-like regime with Zhang-Rice singlets is replaced by local triplet states at realistic values of charge-transfer energy, which would suggest a rather different superconductivity scenario from high-Tc cuprates. We address this competition by investigating Ni4O8 clusters with periodic boundary conditions in the parameter range relevant for the superconducting nickelates. With increasing value of charge-transfer energy we observe upon hole doping the expected crossover from the cuprate regime dominated by Zhang-Rice singlets to the local triplet states. We find that smaller charge-transfer energy is able to drive this change of the ground state character when realistic values for nickel-oxygen repulsion Udp are taken into account. For large values of the charge-transfer energy, oxygen orbitals are less important than in superconducting cuprates as their spectral weight is found only at rather high excitation energies. However, a second Ni(3d) orbital can easily become relevant, with either the xy or the 3z2-r2 orbitals contributing in addition to the x2-y2 orbital to the formation of triplet states. In addition, our result that Udp (acting between Ni and O) favors onsite triplets implies that correlation effects beyond purely onsite interactions should be taken into account when obtaining effective two-band models.