Resolving the Electronic Ground State of La3Ni2O7-{\delta} Films

TL;DR

This study investigates the electronic ground state of La3Ni2O7-{eta} films, revealing charge transfer characteristics, orbital configurations, and magnetic ordering, which are crucial for understanding its superconductivity under high pressure.

Contribution

The paper uncovers the electronic and magnetic ground states of La3Ni2O7-{eta} films using advanced spectroscopy and scattering techniques, highlighting orbital and magnetic orderings relevant to superconductivity.

Findings

Charge transfer nature similar to cuprates

Identification of Zhang-Rice singlets and orbital configurations

Detection of collinear antiferromagnetic order

Abstract

The recent discovery of a superconductivity signature in La3Ni2O7-{\delta} under a pressure of 14 GPa, with a superconducting transition temperature of around 80 K, has attracted considerable attention. An important aspect of investigating electronic structures is discerning the extent to which the electronic ground state of La3Ni2O7-{\delta} resembles the parent state of the cuprate superconductor, a charge transfer insulator with long-range antiferromagnetism. Through X-ray absorption spectroscopy, we have uncovered the crucial influence of oxygen ligands on the electronic ground states of the Ni ions, displaying a charge transfer nature akin to cuprate but with distinct orbital configurations. Both in-plane and out-of-plane Zhang-Rice singlets associated with Ni d_(x^2-y^2 ) and d_(z^2) orbitals are identified, together with a strong interlayer coupling through inner apical oxygen. Additionally, in La3Ni2O7-{\delta} films, we have detected a superlattice reflection (1/4, 1/4, L) at the Ni L absorption edge using resonant X-ray scattering measurements. Further examination of the resonance profile indicates that the reflection originates from the Ni d orbitals. By evaluating the reflection's azimuthal angle dependence, we have confirmed the presence of collinear antiferromagnetic spin ordering and charge-like anisotropy ordered with the same periodicity. Notably, our findings reveal a microscopic relationship between these two components in the temperature dependence of the scattering intensity of the reflection. This investigation enriches our understanding of high-temperature superconductivity in La3Ni2O7-{\delta} under high pressure.