Formation of unconventional standing waves at graphene edges by valley mixing and pseudospin rotation

Changwon Park; Heejun Yang; Andrew J. Mayne; Gérald Dujardin; Sunae Seo; Young Kuk; Jisoon Ihm; Gunn Kim

doi:10.1073/pnas.1114548108

Formation of unconventional standing waves at graphene edges by valley mixing and pseudospin rotation

Changwon Park
, Heejun Yang
, Andrew J. Mayne
, Gérald Dujardin
, Sunae Seo
, Young Kuk
, Jisoon Ihm
, Gunn Kim

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

47 Scopus citations

Abstract

We investigate the roles of the pseudospin and the valley degeneracy in electron scattering at graphene edges. It is found that they are strongly correlated with charge density modulations of short-wavelength oscillations and slowly decaying beat patterns in the electronic density profile. Theoretical analyses using nearest-neighbor tight-binding methods and first-principles density-functional theory calculations agree well with our experimental data from scanning tunneling microscopy. The armchair edge shows almost perfect intervalley scattering with pseudospin invariance regardless of the presence of the hydrogen atom at the edge, whereas the zigzag edge only allows for intravalley scattering with the change in the pseudospin orientation. The effect of structural defects at the graphene edges is also discussed.

Original language	English
Pages (from-to)	18622-18625
Number of pages	4
Journal	Proceedings of the National Academy of Sciences of the United States of America
Volume	108
Issue number	46
DOIs	https://doi.org/10.1073/pnas.1114548108
State	Published - 15 Nov 2011

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title = "Formation of unconventional standing waves at graphene edges by valley mixing and pseudospin rotation",

abstract = "We investigate the roles of the pseudospin and the valley degeneracy in electron scattering at graphene edges. It is found that they are strongly correlated with charge density modulations of short-wavelength oscillations and slowly decaying beat patterns in the electronic density profile. Theoretical analyses using nearest-neighbor tight-binding methods and first-principles density-functional theory calculations agree well with our experimental data from scanning tunneling microscopy. The armchair edge shows almost perfect intervalley scattering with pseudospin invariance regardless of the presence of the hydrogen atom at the edge, whereas the zigzag edge only allows for intravalley scattering with the change in the pseudospin orientation. The effect of structural defects at the graphene edges is also discussed.",

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T1 - Formation of unconventional standing waves at graphene edges by valley mixing and pseudospin rotation

AU - Park, Changwon

AU - Yang, Heejun

AU - Mayne, Andrew J.

AU - Dujardin, Gérald

AU - Seo, Sunae

AU - Kuk, Young

AU - Ihm, Jisoon

AU - Kim, Gunn

PY - 2011/11/15

Y1 - 2011/11/15

N2 - We investigate the roles of the pseudospin and the valley degeneracy in electron scattering at graphene edges. It is found that they are strongly correlated with charge density modulations of short-wavelength oscillations and slowly decaying beat patterns in the electronic density profile. Theoretical analyses using nearest-neighbor tight-binding methods and first-principles density-functional theory calculations agree well with our experimental data from scanning tunneling microscopy. The armchair edge shows almost perfect intervalley scattering with pseudospin invariance regardless of the presence of the hydrogen atom at the edge, whereas the zigzag edge only allows for intravalley scattering with the change in the pseudospin orientation. The effect of structural defects at the graphene edges is also discussed.

AB - We investigate the roles of the pseudospin and the valley degeneracy in electron scattering at graphene edges. It is found that they are strongly correlated with charge density modulations of short-wavelength oscillations and slowly decaying beat patterns in the electronic density profile. Theoretical analyses using nearest-neighbor tight-binding methods and first-principles density-functional theory calculations agree well with our experimental data from scanning tunneling microscopy. The armchair edge shows almost perfect intervalley scattering with pseudospin invariance regardless of the presence of the hydrogen atom at the edge, whereas the zigzag edge only allows for intravalley scattering with the change in the pseudospin orientation. The effect of structural defects at the graphene edges is also discussed.

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JF - Proceedings of the National Academy of Sciences of the United States of America

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Formation of unconventional standing waves at graphene edges by valley mixing and pseudospin rotation

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