Proposed ordering of textured spin singlets in a bulk infinite layer nickelate

Abstract

The infinite-layer structure nickelate Ba2NiO2(AgSe)2 (BNOAS) with d8 Ni ions and a peculiar susceptibility (T) is studied with correlated density functional methods. The overriding feature of the calculations is violation of Hund's rule coupled with complete but unconventional spin-orbital polarization, leading to an unexpected low spin 1B1, "off-diagonal singlet" (ODS) textured by an internal orbital structure of compensating dx2-y2 and dz2 spins. This unconventional configuration has lower energy than conventional high-spin or low-spin alternatives. An electronic transition is obtained at a critical Ni-O separation dcNi-O=2.03 , above which Ni becomes magnetic in square planar NiO2 compounds. We propose scenarios for the signature of magnetic reconstruction in (T) at Tm=130 K without any Curie-Weiss background (no moment) that invoke ordering of Ni d8 moieties that are largely this generalized Kondo singlet. The underlying physics of this system is modeled by a Kondo sieve model (2D Kondo necklace) of a "Kondo" dz2 spin on each site, coupled to a dx2-y2 spin that is itself strongly coupled to neighboring like-spins within the layer. The observed magnetic order places BNOAS below the quantum critical point of the Kondo sieve model, providing a realization of the previously unreported long-range ordered near-singlet weak antiferromagnetic phase. We propose electron doping experiments that would drive the system toward a d9-δ configuration and possible superconductivity with similarity to the recently reported Ba2CuO3.2 that superconducts at 73 K.