Giant orbital polarization of Ni2+ in square planar environment

Abstract

Understanding the electronic behavior of Ni2+ in a square planar environment of oxygen is the key to unravel the origin of the recently discovered superconductivity in the hole doped nickelate Nd0.8Sr0.2NiO2. To identify the major similarities/dissimilarities between nickelate and cuprate superconductivity, the study of the electronic structure of Ni2+ and Cu2+ in an identical square planar environment is essential. In order to address these questions, we investigate the electronic structure of Sr2CuO3 and Ni doped Sr2CuO3 single crystals containing (Cu/Ni)O4 square planar units. Our polarization dependent X-ray absorption spectroscopy experiments for Ni in Sr2Cu0.9Ni0.1O3 have revealed very large orbital polarization, which is a characteristic feature of high Tc cuprate. This arises due to the low spin S=0 configuration with two holes in Ni 3dx2-y2 orbitals - in contrast to the expected high spin S=1 state from Hund's first rule. The presence of such S=0 Ni2+ in hole doped nickelate would be analogous to the Zhang Rice singlet. However, the Mott Hubbard insulating nature of the NiO4 unit would point towards a different electronic phase space of nickelates, compared to high Tc cuprates.