Quantum dot behavior in bilayer graphene nanoribbons

Minsheng Wang; Emil B. Song; Sejoon Lee; Jianshi Tang; Murong Lang; Caifu Zeng; Guangyu Xu; Yi Zhou; Kang L. Wang

doi:10.1021/nn2027566

Quantum dot behavior in bilayer graphene nanoribbons

Minsheng Wang, Emil B. Song, Sejoon Lee, Jianshi Tang, Murong Lang, Caifu Zeng, Guangyu Xu, Yi Zhou, Kang L. Wang

Division of System Semiconductor

University of California at Los Angeles

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

25 Scopus citations

Abstract

Bilayer graphene has recently earned great attention for its unique electronic properties and commendable use in electronic applications. Here, we report the observation of quantum dot (QD) behaviors in bilayer graphene nanoribbons (BL-GNRs). The periodic Coulomb oscillations indicate the formation of a single quantum dot within the BL-GNR because of the broad distribution function of the carrier concentration fluctuation at the charge neutrality point. The size of the QD changes as we modulate the relative position between the Fermi level and surface potential. Furthermore, the potential barriers forming the QD remain stable at elevated temperatures and external bias. In combination with the observation of transport gaps, our results suggest that the disordered surface potential creates QDs along the ribbon and governs the electronic transport properties in BL-GNRs.

Original language	English
Pages (from-to)	8769-8773
Number of pages	5
Journal	ACS Nano
Volume	5
Issue number	11
DOIs	https://doi.org/10.1021/nn2027566
State	Published - 22 Nov 2011

Keywords

bilayer graphene
Coulomb blockade oscillation
nanoribbon
quantum dot

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10.1021/nn2027566

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title = "Quantum dot behavior in bilayer graphene nanoribbons",

abstract = "Bilayer graphene has recently earned great attention for its unique electronic properties and commendable use in electronic applications. Here, we report the observation of quantum dot (QD) behaviors in bilayer graphene nanoribbons (BL-GNRs). The periodic Coulomb oscillations indicate the formation of a single quantum dot within the BL-GNR because of the broad distribution function of the carrier concentration fluctuation at the charge neutrality point. The size of the QD changes as we modulate the relative position between the Fermi level and surface potential. Furthermore, the potential barriers forming the QD remain stable at elevated temperatures and external bias. In combination with the observation of transport gaps, our results suggest that the disordered surface potential creates QDs along the ribbon and governs the electronic transport properties in BL-GNRs.",

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T1 - Quantum dot behavior in bilayer graphene nanoribbons

AU - Wang, Minsheng

AU - Song, Emil B.

AU - Lee, Sejoon

AU - Tang, Jianshi

AU - Lang, Murong

AU - Zeng, Caifu

AU - Xu, Guangyu

AU - Zhou, Yi

AU - Wang, Kang L.

PY - 2011/11/22

Y1 - 2011/11/22

N2 - Bilayer graphene has recently earned great attention for its unique electronic properties and commendable use in electronic applications. Here, we report the observation of quantum dot (QD) behaviors in bilayer graphene nanoribbons (BL-GNRs). The periodic Coulomb oscillations indicate the formation of a single quantum dot within the BL-GNR because of the broad distribution function of the carrier concentration fluctuation at the charge neutrality point. The size of the QD changes as we modulate the relative position between the Fermi level and surface potential. Furthermore, the potential barriers forming the QD remain stable at elevated temperatures and external bias. In combination with the observation of transport gaps, our results suggest that the disordered surface potential creates QDs along the ribbon and governs the electronic transport properties in BL-GNRs.

AB - Bilayer graphene has recently earned great attention for its unique electronic properties and commendable use in electronic applications. Here, we report the observation of quantum dot (QD) behaviors in bilayer graphene nanoribbons (BL-GNRs). The periodic Coulomb oscillations indicate the formation of a single quantum dot within the BL-GNR because of the broad distribution function of the carrier concentration fluctuation at the charge neutrality point. The size of the QD changes as we modulate the relative position between the Fermi level and surface potential. Furthermore, the potential barriers forming the QD remain stable at elevated temperatures and external bias. In combination with the observation of transport gaps, our results suggest that the disordered surface potential creates QDs along the ribbon and governs the electronic transport properties in BL-GNRs.

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KW - Coulomb blockade oscillation

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KW - quantum dot

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Quantum dot behavior in bilayer graphene nanoribbons

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