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Multicationic interactions mitigating lattice strain in sodium layered cathodes

Author

Listed:
  • Haoji Wang

    (Central South University)

  • Tongchao Liu

    (Argonne National Laboratory)

  • Hongyi Chen

    (Central South University)

  • Yu Mei

    (Central South University
    Argonne National Laboratory)

  • Jinqiang Gao

    (Central South University)

  • Lianshan Ni

    (Central South University)

  • Ningyun Hong

    (Central South University)

  • Jiangnan Huang

    (Central South University)

  • Xinyu Hu

    (Central South University)

  • Wentao Deng

    (Central South University)

  • Guoqiang Zou

    (Central South University)

  • Hongshuai Hou

    (Central South University)

  • Debbie S. Silvester

    (Curtin University)

  • Craig E. Banks

    (Manchester Metropolitan University)

  • Xiaobo Ji

    (Central South University)

  • Khalil Amine

    (Argonne National Laboratory)

Abstract

Transition-metal (TM) layered oxides have emerged as the primary cathode choice for sodium-ion batteries (SIBs) due to their high energy density and sustainable chemistry using non-critical elements. However, their anisotropic lattice strain and stress accumulation during (de)sodiation lead to severe structural degradation, yet an intrinsic strain-depressant approach remains elusive. Herein, we propose entropy regulation with zero Li/Co usage to mitigate harmful lattice displacements and enhance the electrochemical performance of sodium layered cathodes. Our findings demonstrate that high entropy design effectively inhibits TMO6 octahedra distortions upon cycling, as evidenced by hard X-ray absorption spectroscopy, greatly reducing near-surface structural deconstruction and interface side reactions. Furthermore, multicationic interactions driven by configurational entropy thermodynamically mitigate the formation of oxygen defects and strengthen ligand-to-metal coordination. The complementarity inherent in charge compensation within complex systems is unveiled and the restrained lattice parameters deviations without interior volume residuals are successfully achieved. As a result, the multicationic cathode exhibits improved cycling stability and Na+ diffusion kinetics in both half and full cells. The cathode chemistries outlined here broaden the prospects for lattice engineering to alleviate bulk fatigue and open up the possibility to develop an economically viable layered oxides with long durability.

Suggested Citation

  • Haoji Wang & Tongchao Liu & Hongyi Chen & Yu Mei & Jinqiang Gao & Lianshan Ni & Ningyun Hong & Jiangnan Huang & Xinyu Hu & Wentao Deng & Guoqiang Zou & Hongshuai Hou & Debbie S. Silvester & Craig E. B, 2025. "Multicationic interactions mitigating lattice strain in sodium layered cathodes," Nature Communications, Nature, vol. 16(1), pages 1-13, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-59666-6
    DOI: 10.1038/s41467-025-59666-6
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    References listed on IDEAS

    as
    1. Liguang Wang & Tongchao Liu & Tianpin Wu & Jun Lu, 2022. "Strain-retardant coherent perovskite phase stabilized Ni-rich cathode," Nature, Nature, vol. 611(7934), pages 61-67, November.
    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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