Nature Communications (Aug 2024)

Signatures of polarized chiral spin disproportionation in rare earth nickelates

  • Jiarui Li,
  • Robert J. Green,
  • Claribel Domínguez,
  • Abraham Levitan,
  • Yi Tseng,
  • Sara Catalano,
  • Jennifer Fowlie,
  • Ronny Sutarto,
  • Fanny Rodolakis,
  • Lucas Korol,
  • Jessica L. McChesney,
  • John W. Freeland,
  • Dirk Van der Marel,
  • Marta Gibert,
  • Riccardo Comin

DOI
https://doi.org/10.1038/s41467-024-51576-3
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 6

Abstract

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Abstract In rare earth nickelates (RENiO3), electron-lattice coupling drives a concurrent metal-to-insulator and bond disproportionation phase transition whose microscopic origin has long been the subject of active debate. Of several proposed mechanisms, here we test the hypothesis that pairs of self-doped ligand holes spatially condense to provide local spin moments that are antiferromagnetically coupled to Ni spins. These singlet-like states provide a basis for long-range bond and spiral spin order. Using magnetic resonant X-ray scattering on NdNiO3 thin films, we observe the chiral nature of the spin-disproportionated state, with spin spirals propagating along the crystallographic (101)ortho direction. These spin spirals are found to preferentially couple to X-ray helicity, establishing the presence of a hitherto-unobserved macroscopic chirality. The presence of this chiral magnetic configuration suggests a potential multiferroic coupling between the noncollinear magnetic arrangement and improper ferroelectric behavior as observed in prior studies on NdNiO3 (101)ortho films and RENiO3 single crystals. Experimentally-constrained theoretical double-cluster calculations confirm the presence of an energetically stable spin-disproportionated state with Zhang-Rice singlet-like combinations of Ni and ligand moments.