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Design of antiferroelectric polarization configuration for ultrahigh capacitive energy storage via increasing entropy

Author

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  • Yongxiao Zhou

    (University of Science and Technology Beijing
    Harbin Institute of Technology)

  • Tianfu Zhang

    (University of Science and Technology Beijing)

  • Liang Chen

    (University of Science and Technology Beijing)

  • Huifen Yu

    (University of Science and Technology Beijing)

  • Ruiyu Wang

    (University of Science and Technology Beijing
    University of Science and Technology Beijing)

  • Hao Zhang

    (University of Science and Technology Beijing)

  • Jie Wu

    (Hainan University)

  • Shiqing Deng

    (University of Science and Technology Beijing)

  • He Qi

    (University of Science and Technology Beijing
    Hainan University)

  • Chang Zhou

    (University of Science and Technology Beijing
    University of Science and Technology Beijing)

  • Jun Chen

    (University of Science and Technology Beijing
    Hainan University)

Abstract

Electric field induced antiferroelectric-ferroelectric phase transition is a double-edged sword for energy storage properties, which not only offers a congenital superiority with substantial energy storage density but also poses significant challenges such as large polarization hysteresis and poor efficiency, deteriorating the operation and service life of capacitors. Here, entropy increase effect is utilized to simultaneously break the long-range antiferroelectric order and locally adjust the fourfold commensurate modulated polarization configuration, leading to a breakthrough in the trade-off between recoverable energy storge density (14.8 J cm−3) and efficiency (90.2%) in medium-entropy antiferroelectrics. The embedding of non-polar phase regions in the incommensurate antiferroelectric matrices, revealing as a mixture of commensurate, incommensurate, and relaxor antiferroelectric polarization configurations, contributes to the diffuse antiferroelectric-ferroelectric phase transition, enhanced phase transition electric field, delayed polarization saturation, and efficient recovery of polarization. This work demonstrates that controlling local diverse antiferroelectric polarization configurations by increasing entropy is an effective avenue to develop high-performance energy storage antiferroelectrics, with implications that can be extended to other materials and functionalities.

Suggested Citation

  • Yongxiao Zhou & Tianfu Zhang & Liang Chen & Huifen Yu & Ruiyu Wang & Hao Zhang & Jie Wu & Shiqing Deng & He Qi & Chang Zhou & Jun Chen, 2025. "Design of antiferroelectric polarization configuration for ultrahigh capacitive energy storage via increasing entropy," Nature Communications, Nature, vol. 16(1), pages 1-8, December.
    • Handle: RePEc:nat:natcom:v:16:y:2025:i:1:d:10.1038_s41467-025-56194-1
    DOI: 10.1038/s41467-025-56194-1
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    References listed on IDEAS

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    1. Liang Chen & Shiqing Deng & Hui Liu & Jie Wu & He Qi & Jun Chen, 2022. "Giant energy-storage density with ultrahigh efficiency in lead-free relaxors via high-entropy design," Nature Communications, Nature, vol. 13(1), pages 1-8, December.
    2. Zhengqian Fu & Xuefeng Chen & Zhenqin Li & Tengfei Hu & Linlin Zhang & Ping Lu & Shujun Zhang & Genshui Wang & Xianlin Dong & Fangfang Xu, 2020. "Unveiling the ferrielectric nature of PbZrO3-based antiferroelectric materials," Nature Communications, Nature, vol. 11(1), pages 1-8, December.
    3. Nengneng Luo & Kai Han & Matthew J. Cabral & Xiaozhou Liao & Shujun Zhang & Changzhong Liao & Guangzu Zhang & Xiyong Chen & Qin Feng & Jing-Feng Li & Yuezhou Wei, 2020. "Constructing phase boundary in AgNbO3 antiferroelectrics: pathway simultaneously achieving high energy density and efficiency," Nature Communications, Nature, vol. 11(1), pages 1-10, December.
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