Mobility spectrum analysis on three-dimensional topological insulator BiSbTeSe2

Jimin Wang; Alexander Kurzendorfer; Lin Chen; Zhiwei Wang; Yoichi Ando; Yang Xu; Ireneusz Miotkowski; Yong P. Chen; Dieter Weiss

doi:10.1063/5.0047773

Mobility spectrum analysis on three-dimensional topological insulator BiSbTeSe₂

Jimin Wang^*, Alexander Kurzendorfer, Lin Chen, Zhiwei Wang, Yoichi Ando, Yang Xu, Ireneusz Miotkowski, Yong P. Chen, Dieter Weiss^*

^*Corresponding author for this work

School of Physics

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

4 Citations (Scopus)

Abstract

We conducted mobility spectrum analysis on a high quality three dimensional topological insulator film of BiSbTeSe₂ to extract mobility μ and carrier density n. Top and bottom gates were applied to tune the carrier density on top and bottom surfaces independently. At 1.5-K, when the conduction is entirely dominated by the Dirac surface states, we always find two dominant conduction channels (top and bottom surfaces), with However, at sufficiently high temperature, when the bulk contributes, a third channel with maximum mobility opens. Our data show the feasibility of the method to analyze the different conduction channels in a topological insulator, being also promising for other similar material systems.

Original language	English
Article number	253107
Journal	Applied Physics Letters
Volume	118
Issue number	25
DOIs	https://doi.org/10.1063/5.0047773
Publication status	Published - 21 Jun 2021

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title = "Mobility spectrum analysis on three-dimensional topological insulator BiSbTeSe2",

abstract = "We conducted mobility spectrum analysis on a high quality three dimensional topological insulator film of BiSbTeSe2 to extract mobility μ and carrier density n. Top and bottom gates were applied to tune the carrier density on top and bottom surfaces independently. At 1.5-K, when the conduction is entirely dominated by the Dirac surface states, we always find two dominant conduction channels (top and bottom surfaces), with However, at sufficiently high temperature, when the bulk contributes, a third channel with maximum mobility opens. Our data show the feasibility of the method to analyze the different conduction channels in a topological insulator, being also promising for other similar material systems.",

author = "Jimin Wang and Alexander Kurzendorfer and Lin Chen and Zhiwei Wang and Yoichi Ando and Yang Xu and Ireneusz Miotkowski and Chen, {Yong P.} and Dieter Weiss",

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T1 - Mobility spectrum analysis on three-dimensional topological insulator BiSbTeSe2

AU - Wang, Jimin

AU - Kurzendorfer, Alexander

AU - Chen, Lin

AU - Wang, Zhiwei

AU - Ando, Yoichi

AU - Xu, Yang

AU - Miotkowski, Ireneusz

AU - Chen, Yong P.

AU - Weiss, Dieter

PY - 2021/6/21

Y1 - 2021/6/21

N2 - We conducted mobility spectrum analysis on a high quality three dimensional topological insulator film of BiSbTeSe2 to extract mobility μ and carrier density n. Top and bottom gates were applied to tune the carrier density on top and bottom surfaces independently. At 1.5-K, when the conduction is entirely dominated by the Dirac surface states, we always find two dominant conduction channels (top and bottom surfaces), with However, at sufficiently high temperature, when the bulk contributes, a third channel with maximum mobility opens. Our data show the feasibility of the method to analyze the different conduction channels in a topological insulator, being also promising for other similar material systems.

AB - We conducted mobility spectrum analysis on a high quality three dimensional topological insulator film of BiSbTeSe2 to extract mobility μ and carrier density n. Top and bottom gates were applied to tune the carrier density on top and bottom surfaces independently. At 1.5-K, when the conduction is entirely dominated by the Dirac surface states, we always find two dominant conduction channels (top and bottom surfaces), with However, at sufficiently high temperature, when the bulk contributes, a third channel with maximum mobility opens. Our data show the feasibility of the method to analyze the different conduction channels in a topological insulator, being also promising for other similar material systems.

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VL - 118

JO - Applied Physics Letters

JF - Applied Physics Letters

IS - 25

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Mobility spectrum analysis on three-dimensional topological insulator BiSbTeSe₂

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