Gating electron-hole asymmetry in twisted bilayer graphene

Chao Hui Yeh; Yung Chang Lin; Yu Chen Chen; Chun Chieh Lu; Zheng Liu; Kazu Suenaga; Po Wen Chiu

doi:10.1021/nn501775h

Gating electron-hole asymmetry in twisted bilayer graphene

Chao Hui Yeh, Yung Chang Lin, Yu Chen Chen, Chun Chieh Lu, Zheng Liu, Kazu Suenaga, Po Wen Chiu^*

^*Corresponding author for this work

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

21 Citations (Scopus)

Abstract

Electron-hole symmetry is one of the unique properties of graphene that is generally absent in most semiconductors because of the different conduction and valence band structures. Here we report on the manipulation of electron-hole symmetry in the low-energy band structure of twisted bilayer graphene, where symmetric saddle points form in the conduction and valence bands as a result of interlayer coupling. By applying a gate voltage to a twisted bilayer with a critical rotation angle, enhanced electron resonance between the two saddle points can be turned on or off, depending on the electron-hole symmetry near the saddle points. The appearance of a 2D⁺ peak, a gate-tunable Raman feature found near the critical angle, indicates a reduction of Fermi velocity in the vicinity of the saddle point to/from which electrons are inelastically scattered by phonons in the round trip of the double-resonance process.

Original language	English
Pages (from-to)	6962-6969
Number of pages	8
Journal	ACS Nano
Volume	8
Issue number	7
DOIs	https://doi.org/10.1021/nn501775h
Publication status	Published - Jul 22 2014
Externally published	Yes

ASJC Scopus Subject Areas

General Materials Science
General Engineering
General Physics and Astronomy

Keywords

Raman
saddle points
twisted bilayer graphene
van Hove singularity

Access to Document

10.1021/nn501775h

Cite this

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abstract = "Electron-hole symmetry is one of the unique properties of graphene that is generally absent in most semiconductors because of the different conduction and valence band structures. Here we report on the manipulation of electron-hole symmetry in the low-energy band structure of twisted bilayer graphene, where symmetric saddle points form in the conduction and valence bands as a result of interlayer coupling. By applying a gate voltage to a twisted bilayer with a critical rotation angle, enhanced electron resonance between the two saddle points can be turned on or off, depending on the electron-hole symmetry near the saddle points. The appearance of a 2D+ peak, a gate-tunable Raman feature found near the critical angle, indicates a reduction of Fermi velocity in the vicinity of the saddle point to/from which electrons are inelastically scattered by phonons in the round trip of the double-resonance process.",

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AU - Yeh, Chao Hui

AU - Lin, Yung Chang

AU - Chen, Yu Chen

AU - Lu, Chun Chieh

AU - Liu, Zheng

AU - Suenaga, Kazu

AU - Chiu, Po Wen

PY - 2014/7/22

Y1 - 2014/7/22

N2 - Electron-hole symmetry is one of the unique properties of graphene that is generally absent in most semiconductors because of the different conduction and valence band structures. Here we report on the manipulation of electron-hole symmetry in the low-energy band structure of twisted bilayer graphene, where symmetric saddle points form in the conduction and valence bands as a result of interlayer coupling. By applying a gate voltage to a twisted bilayer with a critical rotation angle, enhanced electron resonance between the two saddle points can be turned on or off, depending on the electron-hole symmetry near the saddle points. The appearance of a 2D+ peak, a gate-tunable Raman feature found near the critical angle, indicates a reduction of Fermi velocity in the vicinity of the saddle point to/from which electrons are inelastically scattered by phonons in the round trip of the double-resonance process.

AB - Electron-hole symmetry is one of the unique properties of graphene that is generally absent in most semiconductors because of the different conduction and valence band structures. Here we report on the manipulation of electron-hole symmetry in the low-energy band structure of twisted bilayer graphene, where symmetric saddle points form in the conduction and valence bands as a result of interlayer coupling. By applying a gate voltage to a twisted bilayer with a critical rotation angle, enhanced electron resonance between the two saddle points can be turned on or off, depending on the electron-hole symmetry near the saddle points. The appearance of a 2D+ peak, a gate-tunable Raman feature found near the critical angle, indicates a reduction of Fermi velocity in the vicinity of the saddle point to/from which electrons are inelastically scattered by phonons in the round trip of the double-resonance process.

KW - Raman

KW - saddle points

KW - twisted bilayer graphene

KW - van Hove singularity

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Gating electron-hole asymmetry in twisted bilayer graphene

Abstract

ASJC Scopus Subject Areas

Keywords

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