Silicon nitride gate dielectrics and band gap engineering in graphene layers

Wenjuan Zhu; Deborah Neumayer; Vasili Perebeinos; Phaedon Avouris

doi:10.1021/nl101832y

Silicon nitride gate dielectrics and band gap engineering in graphene layers

Wenjuan Zhu
, Deborah Neumayer
, Vasili Perebeinos
, Phaedon Avouris

Department of Electrical Engineering

IBM

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

147 Scopus citations

Abstract

We show that silicon nitride can provide uniform coverage of graphene in field-effect transistors while preserving the channel mobility. This insulator allowed us to study the maximum channel resistance at the Dirac (neutrality) point as a function of the strength of a perpendicular electric field in top-gated devices with different numbers of graphene layers. Using a simple model to account for surface potential variations (electron-hole puddles) near the Dirac point we estimate the field-induced band gap or band overlap in the different layers.

Original language	English
Pages (from-to)	3572-3576
Number of pages	5
Journal	Nano Letters
Volume	10
Issue number	9
DOIs	https://doi.org/10.1021/nl101832y
State	Published - Sep 8 2010

Keywords

band gap
band overlap
Graphene
mobility
PECVD
silicon nitride

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10.1021/nl101832y

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AB - We show that silicon nitride can provide uniform coverage of graphene in field-effect transistors while preserving the channel mobility. This insulator allowed us to study the maximum channel resistance at the Dirac (neutrality) point as a function of the strength of a perpendicular electric field in top-gated devices with different numbers of graphene layers. Using a simple model to account for surface potential variations (electron-hole puddles) near the Dirac point we estimate the field-induced band gap or band overlap in the different layers.

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KW - band overlap

KW - Graphene

KW - mobility

KW - PECVD

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Silicon nitride gate dielectrics and band gap engineering in graphene layers

Abstract

Keywords

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