Ferroelastic-switching-driven large shear strain and piezoelectricity in a hybrid ferroelectric
Materials that can produce large controllable strains are widely used in shape memory devices, actuators and sensors1,2, and great efforts have been made to improve the strain output3-6. Among them, ferroelastic transitions underpin giant reversible strains in electrically driven ferroelectrics or p...
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sg-ntu-dr.10356-1461952023-02-28T19:53:44Z Ferroelastic-switching-driven large shear strain and piezoelectricity in a hybrid ferroelectric Hu, Yuzhong You, Lu Xu, Bin Li, Tao Morris, Samuel Alexander Li, Yongxin Zhang, Yehui Wang, Xin Lee, Pooi See Fan, Hong Jin Wang, Junling School of Physical and Mathematical Sciences Division of Physics and Applied Physics Science::Physics Engineering::Materials::Functional materials Hybrid Ferroelectric Shear Strain Materials that can produce large controllable strains are widely used in shape memory devices, actuators and sensors1,2, and great efforts have been made to improve the strain output3-6. Among them, ferroelastic transitions underpin giant reversible strains in electrically driven ferroelectrics or piezoelectrics and thermally or magnetically driven shape memory alloys7,8. However, large-strain ferroelastic switching in conventional ferroelectrics is very challenging, while magnetic and thermal controls are not desirable for practical applications. Here we demonstrate a large shear strain of up to 21.5% in a hybrid ferroelectric, C6H5N(CH3)3CdCl3, which is two orders of magnitude greater than that in conventional ferroelectric polymers and oxides. It is achieved by inorganic bond switching and facilitated by structural confinement of the large organic moieties, which prevents undesired 180° polarization switching. Furthermore, Br substitution can soften the bonds, allowing a sizable shear piezoelectric coefficient (d35 ≈ 4,830 pm V-1) at the Br-rich end of the solid solution, C6H5N(CH3)3CdBr3xCl3(1-x). The electromechanical properties of these compounds suggest their potential in lightweight and high-energy-density devices, and the strategy described here could inspire the development of next-generation piezoelectrics and electroactive materials based on hybrid ferroelectrics. Agency for Science, Technology and Research (A*STAR) Ministry of Education (MOE) Accepted version We would like to acknowledge the Facility for Analysis, Characterisation, Testing and Simulation (FACTS) at Nanyang Technological University, Singapore for the use of XRD facilities, X. R. Zhou (School of Materials Science and Engineering, Nanyang Technological University) for the help in piezoelectric measurements, and F. Li (Xi’an Jiaotong University) for the discussion on piezoelectric resonance measurements. L.Y. and B.X. acknowledge the startup funds from Soochow University, and the support from Priority Academic Program Development (PAPD) of Jiangsu Higher Education Institutions. L.Y. also acknowledges the support from the National Natural Science Foundation of China (11774249, 12074278), the Natural Science Foundation of Jiangsu Province (BK20171209), and the Key University Science Research Project of Jiangsu Province (18KJA140004, 20KJA140001). H.J.F.acknowledges the support from AME Individual Research Grant (Grant number: A1883c0004), Agency for Science, Technology, and Research (A*STAR). J.W. acknowledges the support from the Ministry of Education, Singapore (Grant numbers: AcRF Tier 1 118/17 and 189/18) and the startup grant from Southern University of Science and Technology (SUSTech), China. 2021-02-01T06:50:49Z 2021-02-01T06:50:49Z 2021 Journal Article Hu, Y., You, L., Xu, B., Li, T., Morris, S. A., Li, Y., ... Wang, J. (2021). Ferroelastic-switching-driven large shear strain and piezoelectricity in a hybrid ferroelectric. Nature Materials. doi:10.1038/s41563-020-00875-3 1476-1122 https://hdl.handle.net/10356/146195 10.1038/s41563-020-00875-3 33432147 en Nature Materials 10.21979/N9/TK1GDN © 2021 Macmillan Publishers Limited, part of Springer Nature. All rights reserved. This paper was published in Nature Materials and is made available with permission of Macmillan Publishers Limited, part of Springer Nature. application/pdf application/pdf |
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Science::Physics Engineering::Materials::Functional materials Hybrid Ferroelectric Shear Strain Hu, Yuzhong You, Lu Xu, Bin Li, Tao Morris, Samuel Alexander Li, Yongxin Zhang, Yehui Wang, Xin Lee, Pooi See Fan, Hong Jin Wang, Junling Ferroelastic-switching-driven large shear strain and piezoelectricity in a hybrid ferroelectric |
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Materials that can produce large controllable strains are widely used in shape memory devices, actuators and sensors1,2, and great efforts have been made to improve the strain output3-6. Among them, ferroelastic transitions underpin giant reversible strains in electrically driven ferroelectrics or piezoelectrics and thermally or magnetically driven shape memory alloys7,8. However, large-strain ferroelastic switching in conventional ferroelectrics is very challenging, while magnetic and thermal controls are not desirable for practical applications. Here we demonstrate a large shear strain of up to 21.5% in a hybrid ferroelectric, C6H5N(CH3)3CdCl3, which is two orders of magnitude greater than that in conventional ferroelectric polymers and oxides. It is achieved by inorganic bond switching and facilitated by structural confinement of the large organic moieties, which prevents undesired 180° polarization switching. Furthermore, Br substitution can soften the bonds, allowing a sizable shear piezoelectric coefficient (d35 ≈ 4,830 pm V-1) at the Br-rich end of the solid solution, C6H5N(CH3)3CdBr3xCl3(1-x). The electromechanical properties of these compounds suggest their potential in lightweight and high-energy-density devices, and the strategy described here could inspire the development of next-generation piezoelectrics and electroactive materials based on hybrid ferroelectrics. |
author2 |
School of Physical and Mathematical Sciences |
author_facet |
School of Physical and Mathematical Sciences Hu, Yuzhong You, Lu Xu, Bin Li, Tao Morris, Samuel Alexander Li, Yongxin Zhang, Yehui Wang, Xin Lee, Pooi See Fan, Hong Jin Wang, Junling |
format |
Article |
author |
Hu, Yuzhong You, Lu Xu, Bin Li, Tao Morris, Samuel Alexander Li, Yongxin Zhang, Yehui Wang, Xin Lee, Pooi See Fan, Hong Jin Wang, Junling |
author_sort |
Hu, Yuzhong |
title |
Ferroelastic-switching-driven large shear strain and piezoelectricity in a hybrid ferroelectric |
title_short |
Ferroelastic-switching-driven large shear strain and piezoelectricity in a hybrid ferroelectric |
title_full |
Ferroelastic-switching-driven large shear strain and piezoelectricity in a hybrid ferroelectric |
title_fullStr |
Ferroelastic-switching-driven large shear strain and piezoelectricity in a hybrid ferroelectric |
title_full_unstemmed |
Ferroelastic-switching-driven large shear strain and piezoelectricity in a hybrid ferroelectric |
title_sort |
ferroelastic-switching-driven large shear strain and piezoelectricity in a hybrid ferroelectric |
publishDate |
2021 |
url |
https://hdl.handle.net/10356/146195 |
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1759856629112635392 |