The interplay between Zeeman splitting and spin-orbit coupling in InAs nanowires

Bum Kyu Kim; Sang Jun Choi; Jae Cheol Shin; Minsoo Kim; Ye Hwan Ahn; H. S. Sim; Ju Jin Kim; Myung Ho Bae

doi:10.1039/c8nr07728b

The interplay between Zeeman splitting and spin-orbit coupling in InAs nanowires

Bum Kyu Kim, Sang Jun Choi, Jae Cheol Shin, Minsoo Kim, Ye Hwan Ahn, H. S. Sim, Ju Jin Kim, Myung Ho Bae

Department of Electronics & Electrical Engineering

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

2 Scopus citations

Abstract

Coupling of the electron orbital motion and spin, i.e., spin-orbit coupling (SOC) leads to nontrivial changes in energy-level structures, giving rise to various spectroscopies and applications. The SOC in solids generates energy-band inversion or splitting under zero or weak magnetic fields, which is required for topological phases or Majorana fermions. Here, we examined the interplay between the Zeeman splitting and SOC by performing the transport spectroscopy of Landau levels (LLs) in indium arsenide nanowires under a strong magnetic field. We observed the anomalous Zeeman splitting of LLs, which depends on the quantum number of LLs as well as the electron spin. We considered that this observation was attributed to the interplay between the Zeeman splitting and the SOC. Our findings suggest an approach of generating spin-resolved chiral electron transport in nanowires.

Original language	English
Pages (from-to)	23175-23181
Number of pages	7
Journal	Nanoscale
Volume	10
Issue number	48
DOIs	https://doi.org/10.1039/c8nr07728b
State	Published - 28 Dec 2018

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title = "The interplay between Zeeman splitting and spin-orbit coupling in InAs nanowires",

abstract = "Coupling of the electron orbital motion and spin, i.e., spin-orbit coupling (SOC) leads to nontrivial changes in energy-level structures, giving rise to various spectroscopies and applications. The SOC in solids generates energy-band inversion or splitting under zero or weak magnetic fields, which is required for topological phases or Majorana fermions. Here, we examined the interplay between the Zeeman splitting and SOC by performing the transport spectroscopy of Landau levels (LLs) in indium arsenide nanowires under a strong magnetic field. We observed the anomalous Zeeman splitting of LLs, which depends on the quantum number of LLs as well as the electron spin. We considered that this observation was attributed to the interplay between the Zeeman splitting and the SOC. Our findings suggest an approach of generating spin-resolved chiral electron transport in nanowires.",

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T1 - The interplay between Zeeman splitting and spin-orbit coupling in InAs nanowires

AU - Kim, Bum Kyu

AU - Choi, Sang Jun

AU - Shin, Jae Cheol

AU - Kim, Minsoo

AU - Ahn, Ye Hwan

AU - Sim, H. S.

AU - Kim, Ju Jin

AU - Bae, Myung Ho

PY - 2018/12/28

Y1 - 2018/12/28

N2 - Coupling of the electron orbital motion and spin, i.e., spin-orbit coupling (SOC) leads to nontrivial changes in energy-level structures, giving rise to various spectroscopies and applications. The SOC in solids generates energy-band inversion or splitting under zero or weak magnetic fields, which is required for topological phases or Majorana fermions. Here, we examined the interplay between the Zeeman splitting and SOC by performing the transport spectroscopy of Landau levels (LLs) in indium arsenide nanowires under a strong magnetic field. We observed the anomalous Zeeman splitting of LLs, which depends on the quantum number of LLs as well as the electron spin. We considered that this observation was attributed to the interplay between the Zeeman splitting and the SOC. Our findings suggest an approach of generating spin-resolved chiral electron transport in nanowires.

AB - Coupling of the electron orbital motion and spin, i.e., spin-orbit coupling (SOC) leads to nontrivial changes in energy-level structures, giving rise to various spectroscopies and applications. The SOC in solids generates energy-band inversion or splitting under zero or weak magnetic fields, which is required for topological phases or Majorana fermions. Here, we examined the interplay between the Zeeman splitting and SOC by performing the transport spectroscopy of Landau levels (LLs) in indium arsenide nanowires under a strong magnetic field. We observed the anomalous Zeeman splitting of LLs, which depends on the quantum number of LLs as well as the electron spin. We considered that this observation was attributed to the interplay between the Zeeman splitting and the SOC. Our findings suggest an approach of generating spin-resolved chiral electron transport in nanowires.

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The interplay between Zeeman splitting and spin-orbit coupling in InAs nanowires

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