材料科学
电容器
解耦(概率)
电介质
热稳定性
铁电性
储能
工作(物理)
极化(电化学)
陶瓷
大气温度范围
磁滞
极地的
格子(音乐)
凝聚态物理
热的
化学物理
铁电陶瓷
功勋
能量密度
消散
航程(航空)
工程物理
理论(学习稳定性)
电势能
纳米技术
弛豫铁电体
热涨落
铁电聚合物
静电学
陶瓷电容器
光电子学
电压
作者
Shiyu Zhou,Yucheng Zhou,Linhai Li,Zhenhao Fan,Wenfeng Yue,Zhengqian Fu,Xuefeng Chen,Bai‐Xiang Xu,Tengfei Hu,Dawei Wang,Tongqing Yang
标识
DOI:10.1038/s41467-025-63173-z
摘要
The development of dielectric ceramics that simultaneously achieve high energy density and ultra-broad temperature stability remains a fundamental challenge for advanced electrostatic capacitors. Here, we report a high-entropy engineering strategy that transforms conventional relaxor ferroelectric BT-Bi(Mg0.5Zr0.5)O3 into entropy-stabilized BT-H through a dual-phase cationic disorder modulation. By maximizing configurational entropy, this approach induces atomic-scale lattice heterogeneity with reduced size of polar units, and establishes temperature-adaptive multiphase coexistence structure, effectively decoupling polarization configuration from thermal fluctuations. Consequently, the optimized BT-H ceramics exhibit extraordinary recoverable energy density (Wrec) of 8.9 J cm-3, near ideal conversion efficiency (η) of ~ 97.8 % and superior temperature stability of ΔWrec ~±9 % and Δη ~ ±4.8% over a ultrawide operational range (-85-220 °C). This work validates the entropy-mediated cocktail effect, demonstrating that leveraging high-entropy materials to design capacitors with superior integrated energy storage performance is an advanced and viable strategy.
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