Band structure asymmetry of bilayer graphene revealed by infrared spectroscopy

Z. Q. Li; E. A. Henriksen; Z. Jiang; Z. Hao; M. C. Martin; P. Kim; H. L. Stormer; D. N. Basov

doi:10.1103/PhysRevLett.102.037403

Band structure asymmetry of bilayer graphene revealed by infrared spectroscopy

Z. Q. Li
, E. A. Henriksen
, Z. Jiang
, Z. Hao
, M. C. Martin
, P. Kim
, H. L. Stormer
, D. N. Basov

Department of Physics

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

234 Scopus citations

Abstract

We report on infrared spectroscopy of bilayer graphene integrated in gated structures. We observe a significant asymmetry in the optical conductivity upon electrostatic doping of electrons and holes. We show that this finding arises from a marked asymmetry between the valence and conduction bands, which is mainly due to the inequivalence of the two sublattices within the graphene layer and the next-nearest-neighbor interlayer coupling. From the conductivity data, the energy difference of the two sublattices and the interlayer coupling energy are directly determined.

Original language	English
Article number	037403
Journal	Physical Review Letters
Volume	102
Issue number	3
DOIs	https://doi.org/10.1103/PhysRevLett.102.037403
State	Published - Jan 20 2009

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10.1103/PhysRevLett.102.037403

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abstract = "We report on infrared spectroscopy of bilayer graphene integrated in gated structures. We observe a significant asymmetry in the optical conductivity upon electrostatic doping of electrons and holes. We show that this finding arises from a marked asymmetry between the valence and conduction bands, which is mainly due to the inequivalence of the two sublattices within the graphene layer and the next-nearest-neighbor interlayer coupling. From the conductivity data, the energy difference of the two sublattices and the interlayer coupling energy are directly determined.",

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AU - Henriksen, E. A.

AU - Jiang, Z.

AU - Hao, Z.

AU - Martin, M. C.

AU - Kim, P.

AU - Stormer, H. L.

AU - Basov, D. N.

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N2 - We report on infrared spectroscopy of bilayer graphene integrated in gated structures. We observe a significant asymmetry in the optical conductivity upon electrostatic doping of electrons and holes. We show that this finding arises from a marked asymmetry between the valence and conduction bands, which is mainly due to the inequivalence of the two sublattices within the graphene layer and the next-nearest-neighbor interlayer coupling. From the conductivity data, the energy difference of the two sublattices and the interlayer coupling energy are directly determined.

AB - We report on infrared spectroscopy of bilayer graphene integrated in gated structures. We observe a significant asymmetry in the optical conductivity upon electrostatic doping of electrons and holes. We show that this finding arises from a marked asymmetry between the valence and conduction bands, which is mainly due to the inequivalence of the two sublattices within the graphene layer and the next-nearest-neighbor interlayer coupling. From the conductivity data, the energy difference of the two sublattices and the interlayer coupling energy are directly determined.

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Band structure asymmetry of bilayer graphene revealed by infrared spectroscopy

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