Electrically and mechanically driven rotation of polar spirals in a relaxor ferroelectric polymer

Mengfan Guo; Erxiang Xu; Houbing Huang; Changqing Guo; Hetian Chen; Shulin Chen; Shan He; Le Zhou; Jing Ma; Zhonghui Shen; Ben Xu; Di Yi; Peng Gao; Ce Wen Nan; Neil D. Mathur; Yang Shen

doi:10.1038/s41467-023-44395-5

Electrically and mechanically driven rotation of polar spirals in a relaxor ferroelectric polymer

Mengfan Guo^*, Erxiang Xu, Houbing Huang, Changqing Guo, Hetian Chen, Shulin Chen, Shan He, Le Zhou, Jing Ma, Zhonghui Shen, Ben Xu, Di Yi, Peng Gao, Ce Wen Nan, Neil D. Mathur^*, Yang Shen^*

^*Corresponding author for this work

Advanced Research Institute of Multidisciplinary Science

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

Topology created by quasi-continuous spatial variations of a local polarization direction represents an exotic state of matter, but field-driven manipulation has been hitherto limited to creation and destruction. Here we report that relatively small electric or mechanical fields can drive the non-volatile rotation of polar spirals in discretized microregions of the relaxor ferroelectric polymer poly(vinylidene fluoride-ran-trifluoroethylene). These polar spirals arise from the asymmetric Coulomb interaction between vertically aligned helical polymer chains, and can be rotated in-plane through various angles with robust retention. Given also that our manipulation of topological order can be detected via infrared absorption, our work suggests a new direction for the application of complex materials.

Original language	English
Article number	348
Journal	Nature Communications
Volume	15
Issue number	1
DOIs	https://doi.org/10.1038/s41467-023-44395-5
Publication status	Published - Dec 2024

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abstract = "Topology created by quasi-continuous spatial variations of a local polarization direction represents an exotic state of matter, but field-driven manipulation has been hitherto limited to creation and destruction. Here we report that relatively small electric or mechanical fields can drive the non-volatile rotation of polar spirals in discretized microregions of the relaxor ferroelectric polymer poly(vinylidene fluoride-ran-trifluoroethylene). These polar spirals arise from the asymmetric Coulomb interaction between vertically aligned helical polymer chains, and can be rotated in-plane through various angles with robust retention. Given also that our manipulation of topological order can be detected via infrared absorption, our work suggests a new direction for the application of complex materials.",

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T1 - Electrically and mechanically driven rotation of polar spirals in a relaxor ferroelectric polymer

AU - Guo, Mengfan

AU - Xu, Erxiang

AU - Huang, Houbing

AU - Guo, Changqing

AU - Chen, Hetian

AU - Chen, Shulin

AU - He, Shan

AU - Zhou, Le

AU - Ma, Jing

AU - Shen, Zhonghui

AU - Xu, Ben

AU - Yi, Di

AU - Gao, Peng

AU - Nan, Ce Wen

AU - Mathur, Neil D.

AU - Shen, Yang

PY - 2024/12

Y1 - 2024/12

N2 - Topology created by quasi-continuous spatial variations of a local polarization direction represents an exotic state of matter, but field-driven manipulation has been hitherto limited to creation and destruction. Here we report that relatively small electric or mechanical fields can drive the non-volatile rotation of polar spirals in discretized microregions of the relaxor ferroelectric polymer poly(vinylidene fluoride-ran-trifluoroethylene). These polar spirals arise from the asymmetric Coulomb interaction between vertically aligned helical polymer chains, and can be rotated in-plane through various angles with robust retention. Given also that our manipulation of topological order can be detected via infrared absorption, our work suggests a new direction for the application of complex materials.

AB - Topology created by quasi-continuous spatial variations of a local polarization direction represents an exotic state of matter, but field-driven manipulation has been hitherto limited to creation and destruction. Here we report that relatively small electric or mechanical fields can drive the non-volatile rotation of polar spirals in discretized microregions of the relaxor ferroelectric polymer poly(vinylidene fluoride-ran-trifluoroethylene). These polar spirals arise from the asymmetric Coulomb interaction between vertically aligned helical polymer chains, and can be rotated in-plane through various angles with robust retention. Given also that our manipulation of topological order can be detected via infrared absorption, our work suggests a new direction for the application of complex materials.

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Electrically and mechanically driven rotation of polar spirals in a relaxor ferroelectric polymer

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