High electrostrain in a lead-free piezoceramic from a chemopiezoelectric effect

IF 37.2 1区材料科学 Q1 CHEMISTRY, PHYSICAL

Nature Materials Pub Date : 2025-02-26 DOI:10.1038/s41563-024-02092-8

Ze Xu, Xiaoming Shi, Yi-Xuan Liu, Danyang Wang, Hao-Cheng Thong, Yuqi Jiang, Zijie Sha, Zhao Li, Fang-Zhou Yao, Xian-Xian Cai, Hao-Feng Huang, Zhanpeng Xu, Xinyu Jin, Chen-Bo-Wen Li, Xin Zhang, Xiaowei Ren, Zhihao Dong, Chaofeng Wu, Peter Kabakov, Fangyuan Zhu, Feng Chen, Peng Tan, Hao Tian, Haozhi Sha, Rong Yu, Ben Xu, Wen Gong, Xiaohui Wang, Jing-Feng Li, Stephen J. Skinner, Ming Li, Houbing Huang, Shujun Zhang, Ke Wang

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Abstract

Piezoelectric materials are indispensable in electromechanical actuators, which require a large electrostrain with a fast and precise response. By designing a chemopiezoelectric effect, we developed an approach to achieve a high electrostrain of 1.9% under −3 kV mm⁻¹, at 1 Hz, corresponding to an effective piezoelectric coefficient of >6,300 pm V⁻¹ at room temperature in lead-free potassium sodium niobate piezoceramics. This electrostrain has satisfactory fatigue resistance and thermal stability, and low hysteresis, far outperforming existing lead-based and lead-free perovskite counterparts. From tracer diffusion, atomic optical emission spectrometry experiments, combined with machine-learning molecular dynamics and phase-field simulations, we attribute the high electrostrain to short-range hopping of oxygen vacancies near ceramic surfaces under an alternating electric field, which is supported by strain levels reaching 3.0% under the same applied field when the sample was annealed at a low oxygen partial pressure. These findings provide an additional degree of freedom for designing materials on the basis of defect engineering, which will favour not only the electrostrain of piezoelectrics but also the functional properties of a broader range of oxide-based materials.

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来源期刊

Nature Materials 工程技术-材料科学：综合

CiteScore

62.20

自引率

0.70%

发文量

221

审稿时长

3.2 months

期刊介绍： Nature Materials is a monthly multi-disciplinary journal aimed at bringing together cutting-edge research across the entire spectrum of materials science and engineering. It covers all applied and fundamental aspects of the synthesis/processing, structure/composition, properties, and performance of materials. The journal recognizes that materials research has an increasing impact on classical disciplines such as physics, chemistry, and biology. Additionally, Nature Materials provides a forum for the development of a common identity among materials scientists and encourages interdisciplinary collaboration. It takes an integrated and balanced approach to all areas of materials research, fostering the exchange of ideas between scientists involved in different disciplines. Nature Materials is an invaluable resource for scientists in academia and industry who are active in discovering and developing materials and materials-related concepts. It offers engaging and informative papers of exceptional significance and quality, with the aim of influencing the development of society in the future.