Quantum Interferences of Pseudospin-Mediated Atomic-Scale Vortices in Monolayer Graphene

Yu Zhang; Ying Su; Lin He

doi:10.1021/acs.nanolett.0c05066

Quantum Interferences of Pseudospin-Mediated Atomic-Scale Vortices in Monolayer Graphene

Yu Zhang^*, Ying Su, Lin He^*

^*Corresponding author for this work

Advanced Research Institute of Multidisciplinary Science

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

14 Citations (Scopus)

Abstract

A vortex is a universal and significant phenomenon that has been known for centuries. However, creating vortices to the atomic limit has remained elusive. Very recently, it was demonstrated that intervalley scattering induced by the single carbon defect of graphene leads to phase winding over a closed path surrounding the defect. Motivated by this, we demonstrate that the single carbon defects at A and B sublattices of graphene can be regarded as pseudospin-mediated atomic-scale vortices with angular momenta l = +2 and-2, respectively. The quantum interference measurements of the vortices indicate that the vortices cancel each other, resulting in zero total angular momentum, in the |A| = |B| case, and they show aggregate chirality and angular momenta similar to a single vortex of the majority in the |A| |B| case, where |A| (|B|) is the number of vortices with angular momenta l = +2 (l =-2).

Original language	English
Pages (from-to)	2526-2531
Number of pages	6
Journal	Nano Letters
Volume	21
Issue number	6
DOIs	https://doi.org/10.1021/acs.nanolett.0c05066
Publication status	Published - 24 Mar 2021

Keywords

graphene
pseudospin
scanning tunneling microscopy (STM) and spectroscopy (STS)
vortex

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10.1021/acs.nanolett.0c05066

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title = "Quantum Interferences of Pseudospin-Mediated Atomic-Scale Vortices in Monolayer Graphene",

abstract = "A vortex is a universal and significant phenomenon that has been known for centuries. However, creating vortices to the atomic limit has remained elusive. Very recently, it was demonstrated that intervalley scattering induced by the single carbon defect of graphene leads to phase winding over a closed path surrounding the defect. Motivated by this, we demonstrate that the single carbon defects at A and B sublattices of graphene can be regarded as pseudospin-mediated atomic-scale vortices with angular momenta l = +2 and-2, respectively. The quantum interference measurements of the vortices indicate that the vortices cancel each other, resulting in zero total angular momentum, in the |A| = |B| case, and they show aggregate chirality and angular momenta similar to a single vortex of the majority in the |A| |B| case, where |A| (|B|) is the number of vortices with angular momenta l = +2 (l =-2).",

keywords = "graphene, pseudospin, scanning tunneling microscopy (STM) and spectroscopy (STS), vortex",

author = "Yu Zhang and Ying Su and Lin He",

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TY - JOUR

T1 - Quantum Interferences of Pseudospin-Mediated Atomic-Scale Vortices in Monolayer Graphene

AU - Zhang, Yu

AU - Su, Ying

AU - He, Lin

PY - 2021/3/24

Y1 - 2021/3/24

N2 - A vortex is a universal and significant phenomenon that has been known for centuries. However, creating vortices to the atomic limit has remained elusive. Very recently, it was demonstrated that intervalley scattering induced by the single carbon defect of graphene leads to phase winding over a closed path surrounding the defect. Motivated by this, we demonstrate that the single carbon defects at A and B sublattices of graphene can be regarded as pseudospin-mediated atomic-scale vortices with angular momenta l = +2 and-2, respectively. The quantum interference measurements of the vortices indicate that the vortices cancel each other, resulting in zero total angular momentum, in the |A| = |B| case, and they show aggregate chirality and angular momenta similar to a single vortex of the majority in the |A| |B| case, where |A| (|B|) is the number of vortices with angular momenta l = +2 (l =-2).

AB - A vortex is a universal and significant phenomenon that has been known for centuries. However, creating vortices to the atomic limit has remained elusive. Very recently, it was demonstrated that intervalley scattering induced by the single carbon defect of graphene leads to phase winding over a closed path surrounding the defect. Motivated by this, we demonstrate that the single carbon defects at A and B sublattices of graphene can be regarded as pseudospin-mediated atomic-scale vortices with angular momenta l = +2 and-2, respectively. The quantum interference measurements of the vortices indicate that the vortices cancel each other, resulting in zero total angular momentum, in the |A| = |B| case, and they show aggregate chirality and angular momenta similar to a single vortex of the majority in the |A| |B| case, where |A| (|B|) is the number of vortices with angular momenta l = +2 (l =-2).

KW - graphene

KW - pseudospin

KW - scanning tunneling microscopy (STM) and spectroscopy (STS)

KW - vortex

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U2 - 10.1021/acs.nanolett.0c05066

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ER -

Quantum Interferences of Pseudospin-Mediated Atomic-Scale Vortices in Monolayer Graphene

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Keywords

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