A snapshot of domain evolution between topological vortex and stripe in ferroelectric hexagonal ErMnO3

Jiaqian Kang; Ziyan Gao; Changqing Guo; Wenfu Zhu; Houbing Huang; Jiawang Hong; Sang Wook Cheong; Xueyun Wang

doi:10.1063/5.0138096

A snapshot of domain evolution between topological vortex and stripe in ferroelectric hexagonal ErMnO₃

Jiaqian Kang, Ziyan Gao, Changqing Guo, Wenfu Zhu, Houbing Huang, Jiawang Hong, Sang Wook Cheong, Xueyun Wang^*

^*Corresponding author for this work

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

2 Citations (Scopus)

Abstract

Hexagonal manganites exhibit three distinct domain patterns: stripe, loop, and vortex. Due to the high ferroelectric phase transition temperature and the lack of reliable visualization methods, it is still a mystery about the evolution and the formation of vortex networks. In this study, we managed to capture the coexistence of vortices, loops, and stripes by accurately controlling the annealing temperature right at Tc. We proposed a merging process between the V-AV pair and the stripe, which result in two different forms of vortex networks, namely, the normal vortex and the zigzag vortex. In addition, the connection between the density of stripes and the orientation of V-AV pairs is analyzed, which are both influenced by self-straining of the crystal. The mystery of evolution of the vortex network is unveiled by capturing the snapshot, and the experimental database provided calls for more analysis to understand the evolution of different domain topologies.

Original language	English
Article number	124102
Journal	Journal of Applied Physics
Volume	133
Issue number	12
DOIs	https://doi.org/10.1063/5.0138096
Publication status	Published - 28 Mar 2023

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title = "A snapshot of domain evolution between topological vortex and stripe in ferroelectric hexagonal ErMnO3",

abstract = "Hexagonal manganites exhibit three distinct domain patterns: stripe, loop, and vortex. Due to the high ferroelectric phase transition temperature and the lack of reliable visualization methods, it is still a mystery about the evolution and the formation of vortex networks. In this study, we managed to capture the coexistence of vortices, loops, and stripes by accurately controlling the annealing temperature right at Tc. We proposed a merging process between the V-AV pair and the stripe, which result in two different forms of vortex networks, namely, the normal vortex and the zigzag vortex. In addition, the connection between the density of stripes and the orientation of V-AV pairs is analyzed, which are both influenced by self-straining of the crystal. The mystery of evolution of the vortex network is unveiled by capturing the snapshot, and the experimental database provided calls for more analysis to understand the evolution of different domain topologies.",

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T1 - A snapshot of domain evolution between topological vortex and stripe in ferroelectric hexagonal ErMnO3

AU - Kang, Jiaqian

AU - Gao, Ziyan

AU - Guo, Changqing

AU - Zhu, Wenfu

AU - Huang, Houbing

AU - Hong, Jiawang

AU - Cheong, Sang Wook

AU - Wang, Xueyun

PY - 2023/3/28

Y1 - 2023/3/28

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AB - Hexagonal manganites exhibit three distinct domain patterns: stripe, loop, and vortex. Due to the high ferroelectric phase transition temperature and the lack of reliable visualization methods, it is still a mystery about the evolution and the formation of vortex networks. In this study, we managed to capture the coexistence of vortices, loops, and stripes by accurately controlling the annealing temperature right at Tc. We proposed a merging process between the V-AV pair and the stripe, which result in two different forms of vortex networks, namely, the normal vortex and the zigzag vortex. In addition, the connection between the density of stripes and the orientation of V-AV pairs is analyzed, which are both influenced by self-straining of the crystal. The mystery of evolution of the vortex network is unveiled by capturing the snapshot, and the experimental database provided calls for more analysis to understand the evolution of different domain topologies.

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A snapshot of domain evolution between topological vortex and stripe in ferroelectric hexagonal ErMnO₃

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