High Electrostrain with Low Hysteresis Realized in Pb-Free Perovskite via Defect Engineering

Huajie Luo; Hui Liu; Zhilun Lu; Shiyu Tang; Bing Xie; Xiaohui Li; Shiqing Deng; Junya Wang; Haibo Zhang; Houbing Huang; Mingxue Tang; Martin T. Dove; Shujun Zhang; Jun Chen

doi:10.1021/acsnano.5c01626

High Electrostrain with Low Hysteresis Realized in Pb-Free Perovskite via Defect Engineering

Huajie Luo (Co-first Author), Hui Liu (Co-first Author), Zhilun Lu (Co-first Author), Shiyu Tang, Bing Xie, Xiaohui Li, Shiqing Deng, Junya Wang, Haibo Zhang, Houbing Huang^*, Mingxue Tang, Martin T. Dove, Shujun Zhang, Jun Chen^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

5 Citations (Scopus)

Abstract

High-precision applications in electromechanical actuation heavily rely on piezoelectric materials that exhibit high electrostrain output with low hysteresis. Here, we report a large electrostrain of 1.53% together with low hysteresis of 12.5%, being achieved by incorporating a nominal oxygen-deficient modifier, SmZnO_2.5, into a Bi_1/2(Na_0.5K_0.5)_1/2TiO₃ matrix. The excellent stability of the skin-like layered structure enables the strain to be maintained over a wide temperature range, spanning from room temperature to 200 °C. The giant strain stems from two main factors, i.e., the defect dipoles with stronger polarization along the [001] direction align with the electric field, thereby enhancing the polarization rotation, as well as the electrobending effect synergistically contributing to these results. Note that strongly polar defect dipoles and dislocations are the key to bending behavior. Importantly, the presence of defect dipoles and dislocations destroys the long-range ferroelectric order, forming 2-5 nm polar nanoregions that induce the observed slim hysteresis behavior. Our research uncovers the potential application of BNT-based materials in actuators with large output displacement and provides a universally applicable methodology to realize large strain with low hysteresis. © 2025 American Chemical Society.

Original language	English
Pages (from-to)	18466-18474
Journal	ACS Nano
Volume	19
Issue number	19
Online published	28 Apr 2025
DOIs	https://doi.org/10.1021/acsnano.5c01626
Publication status	Published - 20 May 2025
Externally published	Yes

Funding

This work was financially supported by the Key Research and Development Program of the Ministry of Science and Technology of China (Grant No. 2022YFB3204000), the Beijing Outstanding Young Scientist Program (JWZQ20240101015), the National Natural Science Foundation of China (Grant Nos. 22235002, 12174274, and 12350710177); China National Postdoctoral Program for Innovative Talents (BX20220033); the Innovation Project of Optics Valley Laboratory (Grant No. OVL2023ZD001). We acknowledge Prof. Xianran Xing of Institute of Solid State Chemistry, University of Science and Technology Beijing provides laboratory X-ray diffraction testing.

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 2 Zero Hunger

Research Keywords

Bi1/2Na1/2TiO3
defect dipoles
electrostrain
lead-free piezoelectric
local structure

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10.1021/acsnano.5c01626

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title = "High Electrostrain with Low Hysteresis Realized in Pb-Free Perovskite via Defect Engineering",

abstract = "High-precision applications in electromechanical actuation heavily rely on piezoelectric materials that exhibit high electrostrain output with low hysteresis. Here, we report a large electrostrain of 1.53% together with low hysteresis of 12.5%, being achieved by incorporating a nominal oxygen-deficient modifier, SmZnO2.5, into a Bi1/2(Na0.5K0.5)1/2TiO3 matrix. The excellent stability of the skin-like layered structure enables the strain to be maintained over a wide temperature range, spanning from room temperature to 200 °C. The giant strain stems from two main factors, i.e., the defect dipoles with stronger polarization along the [001] direction align with the electric field, thereby enhancing the polarization rotation, as well as the electrobending effect synergistically contributing to these results. Note that strongly polar defect dipoles and dislocations are the key to bending behavior. Importantly, the presence of defect dipoles and dislocations destroys the long-range ferroelectric order, forming 2-5 nm polar nanoregions that induce the observed slim hysteresis behavior. Our research uncovers the potential application of BNT-based materials in actuators with large output displacement and provides a universally applicable methodology to realize large strain with low hysteresis. {\textcopyright} 2025 American Chemical Society.",

keywords = "Bi1/2Na1/2TiO3, defect dipoles, electrostrain, lead-free piezoelectric, local structure",

author = "Huajie Luo and Hui Liu and Zhilun Lu and Shiyu Tang and Bing Xie and Xiaohui Li and Shiqing Deng and Junya Wang and Haibo Zhang and Houbing Huang and Mingxue Tang and Dove, {Martin T.} and Shujun Zhang and Jun Chen",

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doi = "10.1021/acsnano.5c01626",

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volume = "19",

pages = "18466--18474",

journal = "ACS Nano",

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TY - JOUR

T1 - High Electrostrain with Low Hysteresis Realized in Pb-Free Perovskite via Defect Engineering

AU - Luo, Huajie

AU - Liu, Hui

AU - Lu, Zhilun

AU - Tang, Shiyu

AU - Xie, Bing

AU - Li, Xiaohui

AU - Deng, Shiqing

AU - Wang, Junya

AU - Zhang, Haibo

AU - Huang, Houbing

AU - Tang, Mingxue

AU - Dove, Martin T.

AU - Zhang, Shujun

AU - Chen, Jun

PY - 2025/5/20

Y1 - 2025/5/20

N2 - High-precision applications in electromechanical actuation heavily rely on piezoelectric materials that exhibit high electrostrain output with low hysteresis. Here, we report a large electrostrain of 1.53% together with low hysteresis of 12.5%, being achieved by incorporating a nominal oxygen-deficient modifier, SmZnO2.5, into a Bi1/2(Na0.5K0.5)1/2TiO3 matrix. The excellent stability of the skin-like layered structure enables the strain to be maintained over a wide temperature range, spanning from room temperature to 200 °C. The giant strain stems from two main factors, i.e., the defect dipoles with stronger polarization along the [001] direction align with the electric field, thereby enhancing the polarization rotation, as well as the electrobending effect synergistically contributing to these results. Note that strongly polar defect dipoles and dislocations are the key to bending behavior. Importantly, the presence of defect dipoles and dislocations destroys the long-range ferroelectric order, forming 2-5 nm polar nanoregions that induce the observed slim hysteresis behavior. Our research uncovers the potential application of BNT-based materials in actuators with large output displacement and provides a universally applicable methodology to realize large strain with low hysteresis. © 2025 American Chemical Society.

AB - High-precision applications in electromechanical actuation heavily rely on piezoelectric materials that exhibit high electrostrain output with low hysteresis. Here, we report a large electrostrain of 1.53% together with low hysteresis of 12.5%, being achieved by incorporating a nominal oxygen-deficient modifier, SmZnO2.5, into a Bi1/2(Na0.5K0.5)1/2TiO3 matrix. The excellent stability of the skin-like layered structure enables the strain to be maintained over a wide temperature range, spanning from room temperature to 200 °C. The giant strain stems from two main factors, i.e., the defect dipoles with stronger polarization along the [001] direction align with the electric field, thereby enhancing the polarization rotation, as well as the electrobending effect synergistically contributing to these results. Note that strongly polar defect dipoles and dislocations are the key to bending behavior. Importantly, the presence of defect dipoles and dislocations destroys the long-range ferroelectric order, forming 2-5 nm polar nanoregions that induce the observed slim hysteresis behavior. Our research uncovers the potential application of BNT-based materials in actuators with large output displacement and provides a universally applicable methodology to realize large strain with low hysteresis. © 2025 American Chemical Society.

KW - Bi1/2Na1/2TiO3

KW - defect dipoles

KW - electrostrain

KW - lead-free piezoelectric

KW - local structure

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JO - ACS Nano

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ER -

High Electrostrain with Low Hysteresis Realized in Pb-Free Perovskite via Defect Engineering

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