Anomalous Behavior of the Ni1+ moment and interstitial band in bi-infinite-layered La3Ni2O5F

Abstract

The discovery of superconductivity in hole-doped Ni1+ systems with "infinite layer" NiO2 square-lattices analogous to the Cu2+ CaCuO2 cuprate has renewed conflicting pictures of the Cu2+-Ni1+ similarity or distinction. Recent synthesis of formal Ni1+ La3Ni2O5F with two infinite NiO2 layers per cell provides a novel member of this class. First principles density functional theory studies reveal an interstitial density derived single band E* in three layers unrelated to any atom, which provides self-doping to a Ni1.09+ ion.The blocking La(O/F)La provides isolation of the NiO2 bilayer and an interstitial E* density to strictly two-dimensional electronic and magnetic systems. Calculations of magnetic tendencies reveals behavior unlike previous nickelates, including vanishing susceptibility up to a large magnetic field. Two dimensional fluctuations and self-doping away from half-filling can account for the lack of observation of a magnetic transition.