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Transition metal vacancy and position engineering enables reversible anionic redox reaction for sodium storage

Author

Listed:
  • Congcong Cai

    (Wuhan University of Technology)

  • Xinyuan Li

    (Wuhan University of Technology)

  • Jiantao Li

    (Argonne National Laboratory)

  • Ruohan Yu

    (Wuhan University of Technology)

  • Ping Hu

    (Wuhan University of Technology)

  • Ting Zhu

    (Wuhan University of Technology)

  • Tianyi Li

    (Argonne National Laboratory)

  • Sungsik Lee

    (Argonne National Laboratory)

  • Nuo Xu

    (Wuhan University of Technology)

  • Hao Fan

    (Wuhan University of Technology)

  • Jinsong Wu

    (Wuhan University of Technology)

  • Liang Zhou

    (Wuhan University of Technology)

  • Liqiang Mai

    (Wuhan University of Technology)

  • Khalil Amine

    (Argonne National Laboratory
    The University of Chicago)

Abstract

Triggering the anionic redox reaction is an effective approach to boost the capacity of layered transition metal (TM) oxides. However, the irreversible oxygen release and structural deterioration at high voltage remain conundrums. Herein, a strategy for Mg ion and vacancy dual doping with partial TM ions pinned in the Na layers is developed to improve both the reversibility of anionic redox reaction and structural stability of layered oxides. Both the Mg ions and vacancies (□) are contained in the TM layers, while partial Mn ions (~1.1%) occupy the Na-sites. The introduced Mg ions combined with vacancies not only create abundant nonbonding O 2p orbitals in favor of high oxygen redox capacity, but also suppress the voltage decay originated from Na–O–□ configuration. The Mn ions pinned in the Na layers act as “rivets” to restrain the slab gliding at extreme de-sodiated state and thereby inhibit the generation of cracks. The positive electrode, Na0.67Mn0.011[Mg0.1□0.07Mn0.83]O2, delivers an enhanced discharge capacity and decent cyclability. This study provides insights into the construction of stable layered oxide positive electrode with highly reversible anionic redox reaction for sodium storage.

Suggested Citation

  • Congcong Cai & Xinyuan Li & Jiantao Li & Ruohan Yu & Ping Hu & Ting Zhu & Tianyi Li & Sungsik Lee & Nuo Xu & Hao Fan & Jinsong Wu & Liang Zhou & Liqiang Mai & Khalil Amine, 2025. "Transition metal vacancy and position engineering enables reversible anionic redox reaction for sodium storage," Nature Communications, Nature, vol. 16(1), pages 1-12, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-024-54998-1
    DOI: 10.1038/s41467-024-54998-1
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    References listed on IDEAS

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    1. Robert A. House & Urmimala Maitra & Miguel A. Pérez-Osorio & Juan G. Lozano & Liyu Jin & James W. Somerville & Laurent C. Duda & Abhishek Nag & Andrew Walters & Ke-Jin Zhou & Matthew R. Roberts & Pete, 2020. "Superstructure control of first-cycle voltage hysteresis in oxygen-redox cathodes," Nature, Nature, vol. 577(7791), pages 502-508, January.
    2. Yu-Jie Guo & Peng-Fei Wang & Yu-Bin Niu & Xu-Dong Zhang & Qinghao Li & Xiqian Yu & Min Fan & Wan-Ping Chen & Yang Yu & Xiangfeng Liu & Qinghai Meng & Sen Xin & Ya-Xia Yin & Yu-Guo Guo, 2021. "Boron-doped sodium layered oxide for reversible oxygen redox reaction in Na-ion battery cathodes," Nature Communications, Nature, vol. 12(1), pages 1-11, December.
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