Pressure-cycling induced transition behaviors of MnBi2Te4

MnBi2Te4 can generate a variety of exotic topological quantum states, which are closely related to its special structure. We conduct comprehensive multiple-cycle high-pressure research on MnBi2Te4 by using a diamond anvil cell to study its phase transition behaviors under high pressure. As observed,...

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Veröffentlicht in:	The Journal of chemical physics 2024-01, Vol.160 (3)
Hauptverfasser:	Wu, Jie, Feng, Yan, Ren, Yifeng, Zhang, Ziyou, Yang, Yanping, Wang, Xinyao, Su, Fuhai, Dong, Hongliang, Lu, Yang, Zhang, Xiaojun, Deng, Yu, Xiang, Bin, Chen, Zhiqiang
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Schlagworte:	Cycles Diamond anvil cells High pressure Phase transitions Topology
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container_title	The Journal of chemical physics
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creator	Wu, Jie Feng, Yan Ren, Yifeng Zhang, Ziyou Yang, Yanping Wang, Xinyao Su, Fuhai Dong, Hongliang Lu, Yang Zhang, Xiaojun Deng, Yu Xiang, Bin Chen, Zhiqiang
description	MnBi2Te4 can generate a variety of exotic topological quantum states, which are closely related to its special structure. We conduct comprehensive multiple-cycle high-pressure research on MnBi2Te4 by using a diamond anvil cell to study its phase transition behaviors under high pressure. As observed, when the pressure does not exceed 15 GPa, the material undergoes an irreversible metal–semiconductor–metal transition, whereas when the pressure exceeds 17 GPa, the layered structure is damaged and becomes irreversibly amorphous due to the lattice distortion caused by compression, but it is not completely amorphous, which presents some nano-sized grains after decompression. Our investigation vividly reveals the phase transition behaviors of MnBi2Te4 under high pressure cycling and paves the experimental way to find topological phases under high pressure.
doi_str_mv	10.1063/5.0184624
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subjects	Cycles Diamond anvil cells High pressure Phase transitions Topology
title	Pressure-cycling induced transition behaviors of MnBi2Te4
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