材料科学
压电
相界
铁电性
陶瓷
电场
压电系数
铁电陶瓷
凝聚态物理
微晶
能量转换
电势能
相(物质)
光电子学
表征(材料科学)
电阻率和电导率
机电耦合系数
工作(物理)
工程物理
材料设计
复合材料
机械能
智能材料
电阻和电导
作者
Minghai Yao,Bo Li,Hanxiao Gao,Gengguang Luo,Lulu Liu,Huaming Wu,Yuan Ze,Jiahong Li,Shenglin Jiang,Guangzu Zhang,Haibo Zhang,Yang Liu
出处
期刊:ACS Nano
[American Chemical Society]
日期:2025-12-16
卷期号:19 (51): 42772-42782
被引量:2
标识
DOI:10.1021/acsnano.5c14163
摘要
Piezoelectric actuators, enabling the conversion of electrical energy into mechanical strain, are pivotal in various electromechanical applications. The morphotropic phase boundary (MPB) approach has been widely used to enhance the electrostrain performance of piezoelectrics. It remains to be explored alternative frameworks beyond the conventional MPB method. Here, a high-entropy strategy is used to enhance the electromechanical response of ferroelectric materials with pristine composition near MPB. By incorporating chemical disorders through the high-entropy strategy, atomic disordered arrangements and severe lattice distortions are induced in the BiFeO3–BaTiO3 (BF-BT) system, thus promoting the formation of nanopolar regions and nanodomain structures, facilitating a more flattened energy profile and mutual phase transformation under an electric field and improving the electromechanical response activity of lattices. As a result, high-entropy BF-BT-based polycrystalline ceramics exhibit an ultrahigh electromechanical response with a giant unipolar electrostrain of 1.23% at 80 kV cm–1 with fatigue-free resistance to cyclic electric fields. The effective converse piezoelectric coefficient (d33*) reaches 1537 pm V–1, surpassing most lead-free piezoelectrics. Our work highlights the potential of high-entropy design in ferroelectric materials as high-performance piezoelectric actuators.
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