Landau level spectrum of bilayer Bernal graphene

J. H. Ho; Y. H. Lai; C. P. Chang; M. F. Lin

doi:10.1016/j.diamond.2008.11.001

Landau level spectrum of bilayer Bernal graphene

J. H. Ho, Y. H. Lai, C. P. Chang, M. F. Lin

Department of Physics

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

3 Citations (Scopus)

Abstract

Landau level spectrum of bilayer Bernal graphene is investigated by using the Peierls Hamiltonian band matrix developed from the tight-binding model. A magnetic field leads a bilayer system to exhibit many dispersionless Landau levels(LLs) at low and high energies and some oscillatory LLs at moderate energy. State degeneracy of the low LLs is two times as much as that of the high LLs. Wave functions and state energies are dominated by the interlayer atomic interactions and field strength (B₀). The former induce two groups of LLs, more low LLs, the asymmetric energy spectrum about the Fermi level, and the change of level spacing. The dependence of the pretty low Landau-level energies on the magnetic field and effective quantum number is approximately linear. An energy gap (E_g) is produced by the magnetic field and interlayer atomic hoppings. E_g grows with the increasing field strength, while it is reduced due to the Zeeman effect. The predicted electronic properties could be verified by the measurements on magneto-optical and transport experiments.

Original language	English
Pages (from-to)	374-379
Number of pages	6
Journal	Diamond and Related Materials
Volume	18
Issue number	2-3
DOIs	https://doi.org/10.1016/j.diamond.2008.11.001
Publication status	Published - 2009 Feb

All Science Journal Classification (ASJC) codes

Electronic, Optical and Magnetic Materials
General Chemistry
Mechanical Engineering
Materials Chemistry
Electrical and Electronic Engineering

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10.1016/j.diamond.2008.11.001

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title = "Landau level spectrum of bilayer Bernal graphene",

abstract = "Landau level spectrum of bilayer Bernal graphene is investigated by using the Peierls Hamiltonian band matrix developed from the tight-binding model. A magnetic field leads a bilayer system to exhibit many dispersionless Landau levels(LLs) at low and high energies and some oscillatory LLs at moderate energy. State degeneracy of the low LLs is two times as much as that of the high LLs. Wave functions and state energies are dominated by the interlayer atomic interactions and field strength (B0). The former induce two groups of LLs, more low LLs, the asymmetric energy spectrum about the Fermi level, and the change of level spacing. The dependence of the pretty low Landau-level energies on the magnetic field and effective quantum number is approximately linear. An energy gap (Eg) is produced by the magnetic field and interlayer atomic hoppings. Eg grows with the increasing field strength, while it is reduced due to the Zeeman effect. The predicted electronic properties could be verified by the measurements on magneto-optical and transport experiments.",

author = "Ho, {J. H.} and Lai, {Y. H.} and Chang, {C. P.} and Lin, {M. F.}",

note = "Funding Information: This work was supported by the National Science Council of Taiwan, under the Grant Nos. NSC 95-2112-M-006-002.",

year = "2009",

month = feb,

doi = "10.1016/j.diamond.2008.11.001",

language = "English",

volume = "18",

pages = "374--379",

journal = "Diamond and Related Materials",

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T1 - Landau level spectrum of bilayer Bernal graphene

AU - Ho, J. H.

AU - Lai, Y. H.

AU - Chang, C. P.

AU - Lin, M. F.

N1 - Funding Information: This work was supported by the National Science Council of Taiwan, under the Grant Nos. NSC 95-2112-M-006-002.

PY - 2009/2

Y1 - 2009/2

N2 - Landau level spectrum of bilayer Bernal graphene is investigated by using the Peierls Hamiltonian band matrix developed from the tight-binding model. A magnetic field leads a bilayer system to exhibit many dispersionless Landau levels(LLs) at low and high energies and some oscillatory LLs at moderate energy. State degeneracy of the low LLs is two times as much as that of the high LLs. Wave functions and state energies are dominated by the interlayer atomic interactions and field strength (B0). The former induce two groups of LLs, more low LLs, the asymmetric energy spectrum about the Fermi level, and the change of level spacing. The dependence of the pretty low Landau-level energies on the magnetic field and effective quantum number is approximately linear. An energy gap (Eg) is produced by the magnetic field and interlayer atomic hoppings. Eg grows with the increasing field strength, while it is reduced due to the Zeeman effect. The predicted electronic properties could be verified by the measurements on magneto-optical and transport experiments.

AB - Landau level spectrum of bilayer Bernal graphene is investigated by using the Peierls Hamiltonian band matrix developed from the tight-binding model. A magnetic field leads a bilayer system to exhibit many dispersionless Landau levels(LLs) at low and high energies and some oscillatory LLs at moderate energy. State degeneracy of the low LLs is two times as much as that of the high LLs. Wave functions and state energies are dominated by the interlayer atomic interactions and field strength (B0). The former induce two groups of LLs, more low LLs, the asymmetric energy spectrum about the Fermi level, and the change of level spacing. The dependence of the pretty low Landau-level energies on the magnetic field and effective quantum number is approximately linear. An energy gap (Eg) is produced by the magnetic field and interlayer atomic hoppings. Eg grows with the increasing field strength, while it is reduced due to the Zeeman effect. The predicted electronic properties could be verified by the measurements on magneto-optical and transport experiments.

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DO - 10.1016/j.diamond.2008.11.001

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SP - 374

EP - 379

JO - Diamond and Related Materials

JF - Diamond and Related Materials

IS - 2-3

ER -

Landau level spectrum of bilayer Bernal graphene

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