Electrostatically Induced Quantum Point Contacts in Bilayer Graphene

Hiske Overweg; Hannah Eggimann; Xi Chen; Sergey Slizovskiy; Marius Eich; Riccardo Pisoni; Yongjin Lee; Peter Rickhaus; Kenji Watanabe; Takashi Taniguchi; Vladimir Fal'Ko; Thomas Ihn; Klaus Ensslin

doi:10.1021/acs.nanolett.7b04666

Electrostatically Induced Quantum Point Contacts in Bilayer Graphene

Hiske Overweg^*
, Hannah Eggimann
, Xi Chen
, Sergey Slizovskiy
, Marius Eich
, Riccardo Pisoni
, Yongjin Lee
, Peter Rickhaus
, Kenji Watanabe
, Takashi Taniguchi
, Vladimir Fal'Ko
, Thomas Ihn
, Klaus Ensslin

^*Corresponding author for this work

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

99 Scopus citations

Abstract

We report the fabrication of electrostatically defined nanostructures in encapsulated bilayer graphene, with leakage resistances below depletion gates as high as R ∼ 10 Gω. This exceeds previously reported values of R = 10-100 k ω.1-3 We attribute this improvement to the use of a graphite back gate. We realize two split gate devices which define an electronic channel on the scale of the Fermi-wavelength. A channel gate covering the gap between the split gates varies the charge carrier density in the channel. We observe device-dependent conductance quantization of ΔG = 2e²/h and ΔG = 4e²/h. In quantizing magnetic fields normal to the sample plane, we recover the four-fold Landau level degeneracy of bilayer graphene. Unexpected mode crossings appear at the crossover between zero magnetic field and the quantum Hall regime.

Original language	English
Pages (from-to)	553-559
Number of pages	7
Journal	Nano Letters
Volume	18
Issue number	1
DOIs	https://doi.org/10.1021/acs.nanolett.7b04666
State	Published - 10 Jan 2018
Externally published	Yes

Bibliographical note

Publisher Copyright:
© 2017 American Chemical Society.

Keywords

band gap
bilayer graphene
displacement field
electrostatic confinement
graphite gate
quantum point contact

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10.1021/acs.nanolett.7b04666

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title = "Electrostatically Induced Quantum Point Contacts in Bilayer Graphene",

abstract = "We report the fabrication of electrostatically defined nanostructures in encapsulated bilayer graphene, with leakage resistances below depletion gates as high as R ∼ 10 Gω. This exceeds previously reported values of R = 10-100 k ω.1-3 We attribute this improvement to the use of a graphite back gate. We realize two split gate devices which define an electronic channel on the scale of the Fermi-wavelength. A channel gate covering the gap between the split gates varies the charge carrier density in the channel. We observe device-dependent conductance quantization of ΔG = 2e2/h and ΔG = 4e2/h. In quantizing magnetic fields normal to the sample plane, we recover the four-fold Landau level degeneracy of bilayer graphene. Unexpected mode crossings appear at the crossover between zero magnetic field and the quantum Hall regime.",

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AU - Overweg, Hiske

AU - Eggimann, Hannah

AU - Chen, Xi

AU - Slizovskiy, Sergey

AU - Eich, Marius

AU - Pisoni, Riccardo

AU - Lee, Yongjin

AU - Rickhaus, Peter

AU - Watanabe, Kenji

AU - Taniguchi, Takashi

AU - Fal'Ko, Vladimir

AU - Ihn, Thomas

AU - Ensslin, Klaus

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Y1 - 2018/1/10

N2 - We report the fabrication of electrostatically defined nanostructures in encapsulated bilayer graphene, with leakage resistances below depletion gates as high as R ∼ 10 Gω. This exceeds previously reported values of R = 10-100 k ω.1-3 We attribute this improvement to the use of a graphite back gate. We realize two split gate devices which define an electronic channel on the scale of the Fermi-wavelength. A channel gate covering the gap between the split gates varies the charge carrier density in the channel. We observe device-dependent conductance quantization of ΔG = 2e2/h and ΔG = 4e2/h. In quantizing magnetic fields normal to the sample plane, we recover the four-fold Landau level degeneracy of bilayer graphene. Unexpected mode crossings appear at the crossover between zero magnetic field and the quantum Hall regime.

AB - We report the fabrication of electrostatically defined nanostructures in encapsulated bilayer graphene, with leakage resistances below depletion gates as high as R ∼ 10 Gω. This exceeds previously reported values of R = 10-100 k ω.1-3 We attribute this improvement to the use of a graphite back gate. We realize two split gate devices which define an electronic channel on the scale of the Fermi-wavelength. A channel gate covering the gap between the split gates varies the charge carrier density in the channel. We observe device-dependent conductance quantization of ΔG = 2e2/h and ΔG = 4e2/h. In quantizing magnetic fields normal to the sample plane, we recover the four-fold Landau level degeneracy of bilayer graphene. Unexpected mode crossings appear at the crossover between zero magnetic field and the quantum Hall regime.

KW - band gap

KW - bilayer graphene

KW - displacement field

KW - electrostatic confinement

KW - graphite gate

KW - quantum point contact

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ER -

Electrostatically Induced Quantum Point Contacts in Bilayer Graphene

Abstract

Bibliographical note

Keywords

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