Dong, G., Hu, Y., Guo, C., Wu, H., Liu, H., Peng, R., Xian, D., Mao, Q., Dong, Y., Zhao, Y., Peng, B., Wang, Z., Hu, Z., Zhang, J., Wang, X., Hong, J., Luo, Z., Ren, W., Ye, Z. G., ... Liu, M. (2022). Self-Assembled Epitaxial Ferroelectric Oxide Nanospring with Super-Scalability. Advanced Materials, 34(13), Article 2108419. https://doi.org/10.1002/adma.202108419
Dong, Guohua ; Hu, Yue ; Guo, Changqing et al. / Self-Assembled Epitaxial Ferroelectric Oxide Nanospring with Super-Scalability. In: Advanced Materials. 2022 ; Vol. 34, No. 13.
@article{ec0c9d83d905432eb2829a189a898546,
title = "Self-Assembled Epitaxial Ferroelectric Oxide Nanospring with Super-Scalability",
abstract = "Oxide nanosprings have attracted many research interests because of their anticorrosion, high-temperature tolerance, oxidation resistance, and enhanced-mechanic-response from unique helix structures, enabling various applications like nanomanipulators, nanomotors, nanoswitches, sensors, and energy harvesters. However, preparing oxide nanosprings is a challenge for their intrinsic lack of elasticity. Here, an approach for preparing self-assembled, epitaxial, ferroelectric nanosprings with built-in strain due to the lattice mismatch in freestanding La0.7Sr0.3MnO3/BaTiO3 (LSMO/BTO) bilayer heterostructures is developed. It is found that these LSMO/BTO nanosprings can be extensively pulled or pushed up to their geometrical limits back and forth without breaking, exhibiting super-scalability with full recovery capability. The phase-field simulations reveal that the excellent scalability originates from the continuous ferroelastic domain structures, resulting from twisting under co-existing axial and shear strains. In addition, the oxide heterostructural springs exhibit strong resilience due to the limited plastic deformation nature and the built-in strain between the bilayers. This discovery provides an alternative way for preparing and operating functional oxide nanosprings that can be applied to various technologies.",
keywords = "elasticity, ferroelectrics, freestanding oxides, polarization, spring",
author = "Guohua Dong and Yue Hu and Changqing Guo and Haijun Wu and Haixia Liu and Ruobo Peng and Dan Xian and Qi Mao and Yongqi Dong and Yanan Zhao and Bin Peng and Zhiguang Wang and Zhongqiang Hu and Junwei Zhang and Xueyun Wang and Jiawang Hong and Zhenlin Luo and Wei Ren and Ye, {Zuo Guang} and Zhuangde Jiang and Ziyao Zhou and Houbing Huang and Yong Peng and Ming Liu",
note = "Publisher Copyright: {\textcopyright} 2022 Wiley-VCH GmbH.",
year = "2022",
month = apr,
day = "1",
doi = "10.1002/adma.202108419",
language = "English",
volume = "34",
journal = "Advanced Materials",
issn = "0935-9648",
publisher = "Wiley-Blackwell",
number = "13",
}
Dong, G, Hu, Y, Guo, C, Wu, H, Liu, H, Peng, R, Xian, D, Mao, Q, Dong, Y, Zhao, Y, Peng, B, Wang, Z, Hu, Z, Zhang, J, Wang, X, Hong, J, Luo, Z, Ren, W, Ye, ZG, Jiang, Z, Zhou, Z, Huang, H, Peng, Y & Liu, M 2022, 'Self-Assembled Epitaxial Ferroelectric Oxide Nanospring with Super-Scalability', Advanced Materials, vol. 34, no. 13, 2108419. https://doi.org/10.1002/adma.202108419
Self-Assembled Epitaxial Ferroelectric Oxide Nanospring with Super-Scalability. / Dong, Guohua; Hu, Yue; Guo, Changqing et al.
In:
Advanced Materials, Vol. 34, No. 13, 2108419, 01.04.2022.
Research output: Contribution to journal › Article › peer-review
TY - JOUR
T1 - Self-Assembled Epitaxial Ferroelectric Oxide Nanospring with Super-Scalability
AU - Dong, Guohua
AU - Hu, Yue
AU - Guo, Changqing
AU - Wu, Haijun
AU - Liu, Haixia
AU - Peng, Ruobo
AU - Xian, Dan
AU - Mao, Qi
AU - Dong, Yongqi
AU - Zhao, Yanan
AU - Peng, Bin
AU - Wang, Zhiguang
AU - Hu, Zhongqiang
AU - Zhang, Junwei
AU - Wang, Xueyun
AU - Hong, Jiawang
AU - Luo, Zhenlin
AU - Ren, Wei
AU - Ye, Zuo Guang
AU - Jiang, Zhuangde
AU - Zhou, Ziyao
AU - Huang, Houbing
AU - Peng, Yong
AU - Liu, Ming
N1 - Publisher Copyright:
© 2022 Wiley-VCH GmbH.
PY - 2022/4/1
Y1 - 2022/4/1
N2 - Oxide nanosprings have attracted many research interests because of their anticorrosion, high-temperature tolerance, oxidation resistance, and enhanced-mechanic-response from unique helix structures, enabling various applications like nanomanipulators, nanomotors, nanoswitches, sensors, and energy harvesters. However, preparing oxide nanosprings is a challenge for their intrinsic lack of elasticity. Here, an approach for preparing self-assembled, epitaxial, ferroelectric nanosprings with built-in strain due to the lattice mismatch in freestanding La0.7Sr0.3MnO3/BaTiO3 (LSMO/BTO) bilayer heterostructures is developed. It is found that these LSMO/BTO nanosprings can be extensively pulled or pushed up to their geometrical limits back and forth without breaking, exhibiting super-scalability with full recovery capability. The phase-field simulations reveal that the excellent scalability originates from the continuous ferroelastic domain structures, resulting from twisting under co-existing axial and shear strains. In addition, the oxide heterostructural springs exhibit strong resilience due to the limited plastic deformation nature and the built-in strain between the bilayers. This discovery provides an alternative way for preparing and operating functional oxide nanosprings that can be applied to various technologies.
AB - Oxide nanosprings have attracted many research interests because of their anticorrosion, high-temperature tolerance, oxidation resistance, and enhanced-mechanic-response from unique helix structures, enabling various applications like nanomanipulators, nanomotors, nanoswitches, sensors, and energy harvesters. However, preparing oxide nanosprings is a challenge for their intrinsic lack of elasticity. Here, an approach for preparing self-assembled, epitaxial, ferroelectric nanosprings with built-in strain due to the lattice mismatch in freestanding La0.7Sr0.3MnO3/BaTiO3 (LSMO/BTO) bilayer heterostructures is developed. It is found that these LSMO/BTO nanosprings can be extensively pulled or pushed up to their geometrical limits back and forth without breaking, exhibiting super-scalability with full recovery capability. The phase-field simulations reveal that the excellent scalability originates from the continuous ferroelastic domain structures, resulting from twisting under co-existing axial and shear strains. In addition, the oxide heterostructural springs exhibit strong resilience due to the limited plastic deformation nature and the built-in strain between the bilayers. This discovery provides an alternative way for preparing and operating functional oxide nanosprings that can be applied to various technologies.
KW - elasticity
KW - ferroelectrics
KW - freestanding oxides
KW - polarization
KW - spring
UR - http://www.scopus.com/inward/record.url?scp=85124751432&partnerID=8YFLogxK
U2 - 10.1002/adma.202108419
DO - 10.1002/adma.202108419
M3 - Article
C2 - 35092066
AN - SCOPUS:85124751432
SN - 0935-9648
VL - 34
JO - Advanced Materials
JF - Advanced Materials
IS - 13
M1 - 2108419
ER -
Dong G, Hu Y, Guo C, Wu H, Liu H, Peng R et al. Self-Assembled Epitaxial Ferroelectric Oxide Nanospring with Super-Scalability. Advanced Materials. 2022 Apr 1;34(13):2108419. doi: 10.1002/adma.202108419
