Interlayer Five-Spin Polaron in Superconducting Bilayer Nickelates

TL;DR

This study investigates the relationship between magnetic order and superconductivity in bilayer nickelates, revealing phase segregation influenced by oxygen stoichiometry and proposing a five-spin polaron as a key ground state feature.

Contribution

It introduces the concept of an interlayer five-spin polaron as a fundamental ground state in superconducting bilayer nickelates, linking electronic structure and oxygen content.

Findings

Superconductivity occurs in SDW-free, oxygen-stoichiometric regions.

Oxygen deficiency promotes SDW order, causing phase segregation.

Distinct electronic structures are observed along the c-axis between domains.

Abstract

The discovery of high-$T_c$ superconductivity in Ruddlesden-Popper nickelates has sparked substantial effort towards understanding unconventional electronic states beyond a traditional cuprate-like d^9 configurational ground state. An understanding of the interplay between magnetic ground states and multi-orbital physics is key for establishing a microscopic mechanism for superconductivity. In the bilayer nickelates, spin density wave (SDW) order is a prominent feature in the non-superconducting regime. However, its relation to superconducting pairing remains an open question. Here, we use resonant x-ray scattering to examine the existence of SDW order in superconducting bilayer nickelate thin films La$_2$PrNi$_2$O$_7$ (LPNO). Comparing superconducting and oxygen-deficient LPNO thin films, we find that superconductivity occurs in SDW-free, oxygen-stoichiometric regions, whereas oxygen-deficiency promotes SDW order, indicating phase segregation of SDW and superconductivity. Furthermore, Ni-$L_3$ and O-$K$ edge spectroscopy reveals distinct electronic structures - particularly along the $c$-axis - between the two domains. Our results identify oxygen stoichiometry as a key parameter controlling interlayer coupling and thus the electronic structure of bilayer nickelates. In concert with theory, we propose that a ligand hole primarily resides at the inter-bilayer apical oxygen, forming a robust interlayer five-spin polaron state, which serves as the ground state for superconducting bilayer nickelates.