Metal-insulator transition in layered nickelates La3Ni2O7-δ (δ=0.0, 0.5, 1)

Abstract

Three low-valence layered nickelates with general formula La3Ni2O7-δ (δ=0.0, 0.5, 1) are studied by ab initio techniques. Both the insulating and metallic limits are analyzed, together with the compound at the Mott transition (δ= 0.5; Ni2+), that shows insulating behavior, with all Ni atoms in a S=1 high-spin state. The compound in the δ= 1 limit (La3Ni2O6), with mean formal valence Ni1.5+ and hence nominally metallic, nevertheless shows a correlated molecular insulating state, produced by the quantum confinement of the NiO2 bilayers and the presence of mainly dz2 bands (bonding-antibonding split) around the gap. The metallic compound shows a larger bandwidth of the eg states that can sustain the experimentally observed paramagnetic metallic properties. The evolution of the in-plane antiferromagnetic coupling with the oxygen content is discussed, and also the similarities of this series of compounds with the layered superconducting cuprates.