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Temperature-dependent dynamic disproportionation in LiNiO2

Author

Listed:
  • Andrey D. Poletayev

    (University of Oxford
    Harwell Science and Innovation Campus)

  • Robert J. Green

    (University of Saskatchewan
    Univ. of British Columbia)

  • Jack E. N. Swallow

    (University of Oxford
    Harwell Science and Innovation Campus)

  • Lijin An

    (University of Oxford
    Harwell Science and Innovation Campus)

  • Leanne Jones

    (University of Oxford
    Harwell Science and Innovation Campus)

  • Grant Harris

    (University of Saskatchewan)

  • Peter Bencok

    (Harwell Science and Innovation Campus)

  • Ronny Sutarto

    (Canadian Light Source)

  • Jonathon P. Cottom

    (Harwell Science and Innovation Campus
    University of Bath
    Advanced Research Center for Nanolithography)

  • Benjamin J. Morgan

    (Harwell Science and Innovation Campus
    University of Bath)

  • Robert A. House

    (University of Oxford
    Harwell Science and Innovation Campus)

  • Robert S. Weatherup

    (University of Oxford
    Harwell Science and Innovation Campus)

  • M. Saiful Islam

    (University of Oxford
    Harwell Science and Innovation Campus
    University of Bath)

Abstract

Nickelate materials offer diverse functionalities for energy and computing applications. Lithium nickel oxide (LiNiO2) is an archetypal layered nickelate, but the electronic structure of this correlated material is not yet fully understood. Here we investigate the temperature-dependent speciation and spin dynamics of Ni ions in LiNiO2. Ab initio simulations predict that Ni ions disproportionate into three states, which dynamically interconvert and whose populations vary with temperature. These predictions are verified using x-ray absorption spectroscopy, x-ray magnetic circular dichroism, and resonant inelastic x-ray scattering at the Ni L3,2-edge. Charge-transfer multiplet calculations consistent with disproportionation reproduce all experimental features. Our results support a model of dynamic disproportionation that explains diverse physical observations of LiNiO2, including magnetometry, thermally activated electronic conduction, diffractometry, core-level spectroscopies, and the stability of ubiquitous antisite defects. This unified understanding of the material properties of LiNiO2 is important for applications of nickelate materials as battery cathodes, catalysts, and superconductors.

Suggested Citation

  • Andrey D. Poletayev & Robert J. Green & Jack E. N. Swallow & Lijin An & Leanne Jones & Grant Harris & Peter Bencok & Ronny Sutarto & Jonathon P. Cottom & Benjamin J. Morgan & Robert A. House & Robert , 2025. "Temperature-dependent dynamic disproportionation in LiNiO2," Nature Communications, Nature, vol. 16(1), pages 1-9, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-64429-4
    DOI: 10.1038/s41467-025-64429-4
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    1. Haoliang Huang & Yu-Chung Chang & Yu-Cheng Huang & Lili Li & Alexander C. Komarek & Liu Hao Tjeng & Yuki Orikasa & Chih-Wen Pao & Ting-Shan Chan & Jin-Ming Chen & Shu-Chih Haw & Jing Zhou & Yifeng Wan, 2023. "Unusual double ligand holes as catalytic active sites in LiNiO2," Nature Communications, Nature, vol. 14(1), pages 1-14, December.
    2. Valentina Bisogni & Sara Catalano & Robert J. Green & Marta Gibert & Raoul Scherwitzl & Yaobo Huang & Vladimir N. Strocov & Pavlo Zubko & Shadi Balandeh & Jean-Marc Triscone & George Sawatzky & Thorst, 2016. "Ground-state oxygen holes and the metal–insulator transition in the negative charge-transfer rare-earth nickelates," Nature Communications, Nature, vol. 7(1), pages 1-8, December.
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