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Generative learning facilitated discovery of high-entropy ceramic dielectrics for capacitive energy storage

Author

Listed:
  • Wei Li

    (Wuhan University of Technology)

  • Zhong-Hui Shen

    (Wuhan University of Technology
    Wuhan University of Technology)

  • Run-Lin Liu

    (Wuhan University of Technology)

  • Xiao-Xiao Chen

    (Wuhan University of Technology)

  • Meng-Fan Guo

    (Tsinghua University)

  • Jin-Ming Guo

    (Hubei University)

  • Hua Hao

    (Wuhan University of Technology)

  • Yang Shen

    (The Pennsylvania State University)

  • Han-Xing Liu

    (Wuhan University of Technology)

  • Long-Qing Chen

    (The Pennsylvania State University)

  • Ce-Wen Nan

    (Tsinghua University)

Abstract

Dielectric capacitors offer great potential for advanced electronics due to their high power densities, but their energy density still needs to be further improved. High-entropy strategy has emerged as an effective method for improving energy storage performance, however, discovering new high-entropy systems within a high-dimensional composition space is a daunting challenge for traditional trial-and-error experiments. Here, based on phase-field simulations and limited experimental data, we propose a generative learning approach to accelerate the discovery of high-entropy dielectrics in a practically infinite exploration space of over 1011 combinations. By encoding-decoding latent space regularities to facilitate data sampling and forward inference, we employ inverse design to screen out the most promising combinations via a ranking strategy. Through only 5 sets of targeted experiments, we successfully obtain a Bi(Mg0.5Ti0.5)O3-based high-entropy dielectric film with a significantly improved energy density of 156 J cm−3 at an electric field of 5104 kV cm−1, surpassing the pristine film by more than eight-fold. This work introduces an effective and innovative avenue for designing high-entropy dielectrics with drastically reduced experimental cycles, which could be also extended to expedite the design of other multicomponent material systems with desired properties.

Suggested Citation

  • Wei Li & Zhong-Hui Shen & Run-Lin Liu & Xiao-Xiao Chen & Meng-Fan Guo & Jin-Ming Guo & Hua Hao & Yang Shen & Han-Xing Liu & Long-Qing Chen & Ce-Wen Nan, 2024. "Generative learning facilitated discovery of high-entropy ceramic dielectrics for capacitive energy storage," Nature Communications, Nature, vol. 15(1), pages 1-10, December.
    • Handle: RePEc:nat:natcom:v:15:y:2024:i:1:d:10.1038_s41467-024-49170-8
    DOI: 10.1038/s41467-024-49170-8
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    References listed on IDEAS

    as
    1. Bingbing Yang & Qinghua Zhang & Houbing Huang & Hao Pan & Wenxuan Zhu & Fanqi Meng & Shun Lan & Yiqian Liu & Bin Wei & Yiqun Liu & Letao Yang & Lin Gu & Long-Qing Chen & Ce-Wen Nan & Yuan-Hua Lin, 2023. "Engineering relaxors by entropy for high energy storage performance," Nature Energy, Nature, vol. 8(9), pages 956-964, September.
    2. Hao Pan & Jing Ma & Ji Ma & Qinghua Zhang & Xiaozhi Liu & Bo Guan & Lin Gu & Xin Zhang & Yu-Jun Zhang & Liangliang Li & Yang Shen & Yuan-Hua Lin & Ce-Wen Nan, 2018. "Giant energy density and high efficiency achieved in bismuth ferrite-based film capacitors via domain engineering," Nature Communications, Nature, vol. 9(1), pages 1-8, December.
    3. Bo Peng & Ye Wei & Yu Qin & Jiabao Dai & Yue Li & Aobo Liu & Yun Tian & Liuliu Han & Yufeng Zheng & Peng Wen, 2023. "Machine learning-enabled constrained multi-objective design of architected materials," Nature Communications, Nature, vol. 14(1), pages 1-12, December.
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