Electron-electron interactions in monolayer graphene quantum capacitors

Xiaolong Chen; Lin Wang; Wei Li; Yang Wang; Zefei Wu; Mingwei Zhang; Yu Han; Yuheng He; Ning Wang

doi:10.1007/s12274-013-0338-2

Electron-electron interactions in monolayer graphene quantum capacitors

Xiaolong Chen, Lin Wang, Wei Li, Yang Wang, Zefei Wu, Mingwei Zhang, Yu Han, Yuheng He, Ning Wang

Hong Kong University of Science and Technology

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

20 Scopus citations

Abstract

We demonstrate the effects of electron-electron (e-e) interactions in monolayer graphene quantum capacitors. Ultrathin yttrium oxide showed excellent performance as the dielectric layer in top-gate device geometry. The structure and dielectric constant of the yttrium oxide layers have been carefully studied. The inverse compressibility retrieved from the quantum capacitance agreed fairly well with the theoretical predictions for the e-e interactions in monolayer graphene at different temperatures. We found that electron-hole puddles played a significant role in the low-density carrier region in graphene. By considering the temperature-dependent charge fluctuation, we established a model to explain the round-off effect originating from the e-e interactions in monolayer graphene near the Dirac point. [Figure not available: see fulltext.]

Original language	English
Pages (from-to)	619-626
Number of pages	8
Journal	Nano Research
Volume	6
Issue number	8
DOIs	https://doi.org/10.1007/s12274-013-0338-2
State	Published - Aug 2013
Externally published	Yes

Keywords

charge fluctuation
e-e interaction
electron-hole puddles
graphene
inverse compressibility
quantum capacitance

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10.1007/s12274-013-0338-2

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title = "Electron-electron interactions in monolayer graphene quantum capacitors",

abstract = "We demonstrate the effects of electron-electron (e-e) interactions in monolayer graphene quantum capacitors. Ultrathin yttrium oxide showed excellent performance as the dielectric layer in top-gate device geometry. The structure and dielectric constant of the yttrium oxide layers have been carefully studied. The inverse compressibility retrieved from the quantum capacitance agreed fairly well with the theoretical predictions for the e-e interactions in monolayer graphene at different temperatures. We found that electron-hole puddles played a significant role in the low-density carrier region in graphene. By considering the temperature-dependent charge fluctuation, we established a model to explain the round-off effect originating from the e-e interactions in monolayer graphene near the Dirac point. [Figure not available: see fulltext.]",

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T1 - Electron-electron interactions in monolayer graphene quantum capacitors

AU - Chen, Xiaolong

AU - Wang, Lin

AU - Li, Wei

AU - Wang, Yang

AU - Wu, Zefei

AU - Zhang, Mingwei

AU - Han, Yu

AU - He, Yuheng

AU - Wang, Ning

PY - 2013/8

Y1 - 2013/8

N2 - We demonstrate the effects of electron-electron (e-e) interactions in monolayer graphene quantum capacitors. Ultrathin yttrium oxide showed excellent performance as the dielectric layer in top-gate device geometry. The structure and dielectric constant of the yttrium oxide layers have been carefully studied. The inverse compressibility retrieved from the quantum capacitance agreed fairly well with the theoretical predictions for the e-e interactions in monolayer graphene at different temperatures. We found that electron-hole puddles played a significant role in the low-density carrier region in graphene. By considering the temperature-dependent charge fluctuation, we established a model to explain the round-off effect originating from the e-e interactions in monolayer graphene near the Dirac point. [Figure not available: see fulltext.]

AB - We demonstrate the effects of electron-electron (e-e) interactions in monolayer graphene quantum capacitors. Ultrathin yttrium oxide showed excellent performance as the dielectric layer in top-gate device geometry. The structure and dielectric constant of the yttrium oxide layers have been carefully studied. The inverse compressibility retrieved from the quantum capacitance agreed fairly well with the theoretical predictions for the e-e interactions in monolayer graphene at different temperatures. We found that electron-hole puddles played a significant role in the low-density carrier region in graphene. By considering the temperature-dependent charge fluctuation, we established a model to explain the round-off effect originating from the e-e interactions in monolayer graphene near the Dirac point. [Figure not available: see fulltext.]

KW - charge fluctuation

KW - e-e interaction

KW - electron-hole puddles

KW - graphene

KW - inverse compressibility

KW - quantum capacitance

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Electron-electron interactions in monolayer graphene quantum capacitors

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Keywords

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