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Autores principales: Zhang, Cheng-Long, Zhao, Yilin, Chen, Yiyuan, Lin, Ziquan, Shao, Sen, Gong, Zhen-Hao, Wang, Junfeng, Lu, Hai-Zhou, Chang, Guoqing, Jia, Shuang
Formato: Preprint
Publicado: 2023
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Acceso en línea:https://arxiv.org/abs/2309.03568
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author Zhang, Cheng-Long
Zhao, Yilin
Chen, Yiyuan
Lin, Ziquan
Shao, Sen
Gong, Zhen-Hao
Wang, Junfeng
Lu, Hai-Zhou
Chang, Guoqing
Jia, Shuang
author_facet Zhang, Cheng-Long
Zhao, Yilin
Chen, Yiyuan
Lin, Ziquan
Shao, Sen
Gong, Zhen-Hao
Wang, Junfeng
Lu, Hai-Zhou
Chang, Guoqing
Jia, Shuang
contents A topological insulator is a quantum material which possesses conducting surfaces and an insulating bulk. Despite extensive researches on the properties of Dirac surface states, the characteristics of bulk states have remained largely unexplored. Here we report the observation of spinor-dominated magnetoresistance anomalies in the topological insulator $β$-Ag$_2$Se, induced by a magnetic-field-driven band topological phase transition. These anomalies are caused by intrinsic orthogonality in the wave-function spinors of the last Landau bands of the bulk states, in which backscattering is strictly forbidden during a band topological phase transition. This new type of longitudinal magnetoresistance, purely controlled by the wave-function spinors of the last Landau bands, highlights a unique signature of electrical transport around the band topological phase transition. With further reducing the quantum limit and gap size in $β$-Ag$_2$Se, our results may also suggest possible device applications based on this spinor-dominated mechanism and signify a rare case where topology enters the realm of magnetoresistance control.
format Preprint
id arxiv_https___arxiv_org_abs_2309_03568
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Spinor-dominated magnetoresistance driven by the topological phase transition in $β$-Ag$_2$Se
Zhang, Cheng-Long
Zhao, Yilin
Chen, Yiyuan
Lin, Ziquan
Shao, Sen
Gong, Zhen-Hao
Wang, Junfeng
Lu, Hai-Zhou
Chang, Guoqing
Jia, Shuang
Mesoscale and Nanoscale Physics
Materials Science
A topological insulator is a quantum material which possesses conducting surfaces and an insulating bulk. Despite extensive researches on the properties of Dirac surface states, the characteristics of bulk states have remained largely unexplored. Here we report the observation of spinor-dominated magnetoresistance anomalies in the topological insulator $β$-Ag$_2$Se, induced by a magnetic-field-driven band topological phase transition. These anomalies are caused by intrinsic orthogonality in the wave-function spinors of the last Landau bands of the bulk states, in which backscattering is strictly forbidden during a band topological phase transition. This new type of longitudinal magnetoresistance, purely controlled by the wave-function spinors of the last Landau bands, highlights a unique signature of electrical transport around the band topological phase transition. With further reducing the quantum limit and gap size in $β$-Ag$_2$Se, our results may also suggest possible device applications based on this spinor-dominated mechanism and signify a rare case where topology enters the realm of magnetoresistance control.
title Spinor-dominated magnetoresistance driven by the topological phase transition in $β$-Ag$_2$Se
topic Mesoscale and Nanoscale Physics
Materials Science
url https://arxiv.org/abs/2309.03568