Intertwined charge and spin instability of La3Ni2O7

Abstract

Research on nickel-based superconductors has progressed from infinite-layer LaNiO2 to finite-layer La6Ni5O12, and most recently to the Ruddlesden-Popper phase La3Ni2O7, which was found to exhibits onset of superconductivity at 80\,K under a pressure of 16\,GPa. Unlike the superconductivity mainly driven by the dx2-y2 orbital in infinite-layer nickelates, the Ni-dz2 and O-2p orbitals contribute significantly to the low energy states and potentially to the superconducting electron pairing mechanism of La3Ni2O7. Employing density functional calculations and multi-orbital multi-atom cluster exact diagonalization including local exchange and Coulomb interactions, here we analyze the pressure dependent low-energy electronic states of the Ni2O9 cluster, relevant for the bilayer phase of La3Ni2O7. The various possible spin states and the exchange and superexchange mechanisms of the Ni2O9 cluster are quantified via the involvement of the Ni-3d3z2-r2 orbitals and the atomic Hund's rule exchange, the apical bridging O-2pz orbitals, and the orbitals involved in the formation of local Zhang-Rice singlet like states. We find that the leading configurations contributiong to the cluster ground-states both for nominal valence and also with local charge fluctuations, do not involve occupation of the apical oxygen, instead they favor formation of in-plane Zhang-Rice singlet like states between an O ligand hole and the Ni 3dz2-y2 orbital. We also highlight two possible charge and spin ordered states suggested by our cluster results, that are nearly degenerate at all relevant pressures within our modelling.

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