Stretchable polymer composites with ultrahigh piezoelectric performance

Tongxiang Tang; Zhonghui Shen; Jian Wang; Shiqi Xu; Jiaxi Jiang; Jiahui Chang; Mengfan Guo; Youjun Fan; Yao Xiao; Zhihao Dong; Houbing Huang; Xiaoyan Li; Yihui Zhang; Danyang Wang; Long Qing Chen; Ke Wang; Shujun Zhang; Ce Wen Nan; Yang Shen

doi:10.1093/nsr/nwad177

Stretchable polymer composites with ultrahigh piezoelectric performance

Tongxiang Tang, Zhonghui Shen, Jian Wang, Shiqi Xu, Jiaxi Jiang, Jiahui Chang, Mengfan Guo, Youjun Fan, Yao Xiao, Zhihao Dong, Houbing Huang, Xiaoyan Li, Yihui Zhang, Danyang Wang, Long Qing Chen, Ke Wang, Shujun Zhang^*, Ce Wen Nan^*, Yang Shen^*

^*此作品的通讯作者

前沿交叉科学研究院

科研成果: 期刊稿件 › 文章 › 同行评审

21 引用（Scopus）

摘要

Flexible piezoelectric materials capable of withstanding large deformation play key roles in flexible electronics. Ferroelectric ceramics with a high piezoelectric coefficient are inherently brittle, whereas polar polymers exhibit a low piezoelectric coefficient. Here we report a highly stretchable/compressible piezoelectric composite composed of ferroelectric ceramic skeleton, elastomer matrix and relaxor ferroelectric-based hybrid at the ceramic/matrix interface as dielectric transition layers, exhibiting a giant piezoelectric coefficient of 250 picometers per volt, high electromechanical coupling factor keff of 65%, ultralow acoustic impedance of 3MRyl and high cyclic stability under 50% compression strain. The superior flexibility and piezoelectric properties are attributed to the electric polarization and mechanical load transfer paths formed by the ceramic skeleton, and dielectric mismatch mitigation between ceramic fillers and elastomer matrix by the dielectric transition layer. The synergistic fusion of ultrahigh piezoelectric properties and superior flexibility in these polymer composites is expected to drive emerging applications in flexible smart electronics.

源语言	英语
文章编号	nwad177
期刊	National Science Review
卷	10
期	8
DOI	https://doi.org/10.1093/nsr/nwad177
出版状态	已出版 - 1 8月 2023

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Tang, T., Shen, Z., Wang, J., Xu, S., Jiang, J., Chang, J., Guo, M., Fan, Y., Xiao, Y., Dong, Z., Huang, H., Li, X., Zhang, Y., Wang, D., Chen, L. Q., Wang, K., Zhang, S., Nan, C. W., & Shen, Y. (2023). Stretchable polymer composites with ultrahigh piezoelectric performance. National Science Review, 10(8), 文章 nwad177. https://doi.org/10.1093/nsr/nwad177

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title = "Stretchable polymer composites with ultrahigh piezoelectric performance",

abstract = "Flexible piezoelectric materials capable of withstanding large deformation play key roles in flexible electronics. Ferroelectric ceramics with a high piezoelectric coefficient are inherently brittle, whereas polar polymers exhibit a low piezoelectric coefficient. Here we report a highly stretchable/compressible piezoelectric composite composed of ferroelectric ceramic skeleton, elastomer matrix and relaxor ferroelectric-based hybrid at the ceramic/matrix interface as dielectric transition layers, exhibiting a giant piezoelectric coefficient of 250 picometers per volt, high electromechanical coupling factor keff of 65%, ultralow acoustic impedance of 3MRyl and high cyclic stability under 50% compression strain. The superior flexibility and piezoelectric properties are attributed to the electric polarization and mechanical load transfer paths formed by the ceramic skeleton, and dielectric mismatch mitigation between ceramic fillers and elastomer matrix by the dielectric transition layer. The synergistic fusion of ultrahigh piezoelectric properties and superior flexibility in these polymer composites is expected to drive emerging applications in flexible smart electronics.",

keywords = "flexible electronics, piezoelectric materials, polymer composites, structure design",

author = "Tongxiang Tang and Zhonghui Shen and Jian Wang and Shiqi Xu and Jiaxi Jiang and Jiahui Chang and Mengfan Guo and Youjun Fan and Yao Xiao and Zhihao Dong and Houbing Huang and Xiaoyan Li and Yihui Zhang and Danyang Wang and Chen, {Long Qing} and Ke Wang and Shujun Zhang and Nan, {Ce Wen} and Yang Shen",

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doi = "10.1093/nsr/nwad177",

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AU - Tang, Tongxiang

AU - Shen, Zhonghui

AU - Wang, Jian

AU - Xu, Shiqi

AU - Jiang, Jiaxi

AU - Chang, Jiahui

AU - Guo, Mengfan

AU - Fan, Youjun

AU - Xiao, Yao

AU - Dong, Zhihao

AU - Huang, Houbing

AU - Li, Xiaoyan

AU - Zhang, Yihui

AU - Wang, Danyang

AU - Chen, Long Qing

AU - Wang, Ke

AU - Zhang, Shujun

AU - Nan, Ce Wen

AU - Shen, Yang

PY - 2023/8/1

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N2 - Flexible piezoelectric materials capable of withstanding large deformation play key roles in flexible electronics. Ferroelectric ceramics with a high piezoelectric coefficient are inherently brittle, whereas polar polymers exhibit a low piezoelectric coefficient. Here we report a highly stretchable/compressible piezoelectric composite composed of ferroelectric ceramic skeleton, elastomer matrix and relaxor ferroelectric-based hybrid at the ceramic/matrix interface as dielectric transition layers, exhibiting a giant piezoelectric coefficient of 250 picometers per volt, high electromechanical coupling factor keff of 65%, ultralow acoustic impedance of 3MRyl and high cyclic stability under 50% compression strain. The superior flexibility and piezoelectric properties are attributed to the electric polarization and mechanical load transfer paths formed by the ceramic skeleton, and dielectric mismatch mitigation between ceramic fillers and elastomer matrix by the dielectric transition layer. The synergistic fusion of ultrahigh piezoelectric properties and superior flexibility in these polymer composites is expected to drive emerging applications in flexible smart electronics.

AB - Flexible piezoelectric materials capable of withstanding large deformation play key roles in flexible electronics. Ferroelectric ceramics with a high piezoelectric coefficient are inherently brittle, whereas polar polymers exhibit a low piezoelectric coefficient. Here we report a highly stretchable/compressible piezoelectric composite composed of ferroelectric ceramic skeleton, elastomer matrix and relaxor ferroelectric-based hybrid at the ceramic/matrix interface as dielectric transition layers, exhibiting a giant piezoelectric coefficient of 250 picometers per volt, high electromechanical coupling factor keff of 65%, ultralow acoustic impedance of 3MRyl and high cyclic stability under 50% compression strain. The superior flexibility and piezoelectric properties are attributed to the electric polarization and mechanical load transfer paths formed by the ceramic skeleton, and dielectric mismatch mitigation between ceramic fillers and elastomer matrix by the dielectric transition layer. The synergistic fusion of ultrahigh piezoelectric properties and superior flexibility in these polymer composites is expected to drive emerging applications in flexible smart electronics.

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Stretchable polymer composites with ultrahigh piezoelectric performance

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