Author
Listed:
- Congbing Tan
(Hunan University of Science and Technology
Xiangtan University
Southern University of Science and Technology)
- Yongqi Dong
(Chinese Academy of Sciences
University of Science and Technology of China)
- Yuanwei Sun
(Peking University
Peking University)
- Chang Liu
(Zhejiang University
Southwest Jiaotong University)
- Pan Chen
(Chinese Academy of Sciences)
- Xiangli Zhong
(Xiangtan University)
- Ruixue Zhu
(Peking University
Peking University)
- Mingwei Liu
(Hunan University of Science and Technology)
- Jingmin Zhang
(Peking University)
- Jinbin Wang
(Xiangtan University)
- Kaihui Liu
(Peking University
Collaborative Innovation Centre of Quantum Matter)
- Xuedong Bai
(Chinese Academy of Sciences)
- Dapeng Yu
(Collaborative Innovation Centre of Quantum Matter
Peking University
Shenzhen Key Laboratory of Quantum Science and Engineering)
- Xiaoping Ouyang
(Xiangtan University)
- Jie Wang
(Zhejiang University
Zhejiang University)
- Peng Gao
(Peking University
Peking University
Collaborative Innovation Centre of Quantum Matter
Peking University)
- Zhenlin Luo
(University of Science and Technology of China)
- Jiangyu Li
(Southern University of Science and Technology
Chinese Academy of Sciences
Guangdong Provincial Key Laboratory of Functional Oxide Materials and Devices, Southern University of Science and Technology)
Abstract
Topologically nontrivial polar structures are not only attractive for high-density data storage, but also for ultralow power microelectronics thanks to their exotic negative capacitance. The vast majority of polar structures emerging naturally in ferroelectrics, however, are topologically trivial, and there are enormous interests in artificially engineered polar structures possessing nontrivial topology. Here we demonstrate reconstruction of topologically trivial strip-like domain architecture into arrays of polar vortex in (PbTiO3)10/(SrTiO3)10 superlattice, accomplished by fabricating a cross-sectional lamella from the superlattice film. Using a combination of techniques for polarization mapping, atomic imaging, and three-dimensional structure visualization supported by phase field simulations, we reveal that the reconstruction relieves biaxial epitaxial strain in thin film into a uniaxial one in lamella, changing the subtle electrostatic and elastostatic energetics and providing the driving force for the polar vortex formation. The work establishes a realistic strategy for engineering polar topologies in otherwise ordinary ferroelectric superlattices.
Suggested Citation
Congbing Tan & Yongqi Dong & Yuanwei Sun & Chang Liu & Pan Chen & Xiangli Zhong & Ruixue Zhu & Mingwei Liu & Jingmin Zhang & Jinbin Wang & Kaihui Liu & Xuedong Bai & Dapeng Yu & Xiaoping Ouyang & Jie , 2021.
"Engineering polar vortex from topologically trivial domain architecture,"
Nature Communications, Nature, vol. 12(1), pages 1-8, December.
Handle:
RePEc:nat:natcom:v:12:y:2021:i:1:d:10.1038_s41467-021-24922-y
DOI: 10.1038/s41467-021-24922-y
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Citations
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Cited by:
- Vivasha Govinden & Peiran Tong & Xiangwei Guo & Qi Zhang & Sukriti Mantri & Mohammad Moein Seyfouri & Sergei Prokhorenko & Yousra Nahas & Yongjun Wu & Laurent Bellaiche & Tulai Sun & He Tian & Zijian , 2023.
"Ferroelectric solitons crafted in epitaxial bismuth ferrite superlattices,"
Nature Communications, Nature, vol. 14(1), pages 1-10, December.
- Feng-Hui Gong & Yun-Long Tang & Yu-Jia Wang & Yu-Ting Chen & Bo Wu & Li-Xin Yang & Yin-Lian Zhu & Xiu-Liang Ma, 2023.
"Absence of critical thickness for polar skyrmions with breaking the Kittel’s law,"
Nature Communications, Nature, vol. 14(1), pages 1-9, December.
- Yu-Tsun Shao & Sujit Das & Zijian Hong & Ruijuan Xu & Swathi Chandrika & Fernando Gómez-Ortiz & Pablo García-Fernández & Long-Qing Chen & Harold Y. Hwang & Javier Junquera & Lane W. Martin & Ramamoort, 2023.
"Emergent chirality in a polar meron to skyrmion phase transition,"
Nature Communications, Nature, vol. 14(1), pages 1-9, December.
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