Raman spectroscopy study of rotated double-layer graphene: Misorientation-angle dependence of electronic structure

Kwanpyo Kim; Sinisa Coh; Liang Z. Tan; William Regan; Jong Min Yuk; Eric Chatterjee; M. F. Crommie; Marvin L. Cohen; Steven G. Louie; A. Zettl

doi:10.1103/PhysRevLett.108.246103

Raman spectroscopy study of rotated double-layer graphene: Misorientation-angle dependence of electronic structure

Kwanpyo Kim, Sinisa Coh, Liang Z. Tan, William Regan, Jong Min Yuk, Eric Chatterjee, M. F. Crommie, Marvin L. Cohen, Steven G. Louie, A. Zettl

Department of Physics

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

486 Citations (Scopus)

Abstract

We present a systematic Raman study of unconventionally stacked double-layer graphene, and find that the spectrum strongly depends on the relative rotation angle between layers. Rotation-dependent trends in the position, width and intensity of graphene 2D and G peaks are experimentally established and accounted for theoretically. Our theoretical analysis reveals that changes in electronic band structure due to the interlayer interaction, such as rotational-angle dependent Van Hove singularities, are responsible for the observed spectral features. Our combined experimental and theoretical study provides a deeper understanding of the electronic band structure of rotated double-layer graphene, and leads to a practical way to identify and analyze rotation angles of misoriented double-layer graphene.

Original language	English
Article number	246103
Journal	Physical review letters
Volume	108
Issue number	24
DOIs	https://doi.org/10.1103/PhysRevLett.108.246103
Publication status	Published - 2012 Jun 14

All Science Journal Classification (ASJC) codes

Physics and Astronomy(all)

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10.1103/PhysRevLett.108.246103

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title = "Raman spectroscopy study of rotated double-layer graphene: Misorientation-angle dependence of electronic structure",

abstract = "We present a systematic Raman study of unconventionally stacked double-layer graphene, and find that the spectrum strongly depends on the relative rotation angle between layers. Rotation-dependent trends in the position, width and intensity of graphene 2D and G peaks are experimentally established and accounted for theoretically. Our theoretical analysis reveals that changes in electronic band structure due to the interlayer interaction, such as rotational-angle dependent Van Hove singularities, are responsible for the observed spectral features. Our combined experimental and theoretical study provides a deeper understanding of the electronic band structure of rotated double-layer graphene, and leads to a practical way to identify and analyze rotation angles of misoriented double-layer graphene.",

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T2 - Misorientation-angle dependence of electronic structure

AU - Kim, Kwanpyo

AU - Coh, Sinisa

AU - Tan, Liang Z.

AU - Regan, William

AU - Yuk, Jong Min

AU - Chatterjee, Eric

AU - Crommie, M. F.

AU - Cohen, Marvin L.

AU - Louie, Steven G.

AU - Zettl, A.

PY - 2012/6/14

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AB - We present a systematic Raman study of unconventionally stacked double-layer graphene, and find that the spectrum strongly depends on the relative rotation angle between layers. Rotation-dependent trends in the position, width and intensity of graphene 2D and G peaks are experimentally established and accounted for theoretically. Our theoretical analysis reveals that changes in electronic band structure due to the interlayer interaction, such as rotational-angle dependent Van Hove singularities, are responsible for the observed spectral features. Our combined experimental and theoretical study provides a deeper understanding of the electronic band structure of rotated double-layer graphene, and leads to a practical way to identify and analyze rotation angles of misoriented double-layer graphene.

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Raman spectroscopy study of rotated double-layer graphene: Misorientation-angle dependence of electronic structure

Abstract

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