Enhanced transport and transistor performance with oxide seeded high-κ gate dielectrics on wafer-scale epitaxial graphene

Matthew J. Hollander; Michael Labella; Zachary R. Hughes; Michael Zhu; Kathleen A. Trumbull; Randal Cavalero; David W. Snyder; Xiaojun Wang; Euichul Hwang; Suman Datta; Joshua A. Robinson

doi:10.1021/nl201358y

Enhanced transport and transistor performance with oxide seeded high-κ gate dielectrics on wafer-scale epitaxial graphene

Matthew J. Hollander, Michael Labella, Zachary R. Hughes, Michael Zhu, Kathleen A. Trumbull, Randal Cavalero, David W. Snyder, Xiaojun Wang, Euichul Hwang, Suman Datta, Joshua A. Robinson

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

102 Scopus citations

Abstract

We explore the effect of high-κ dielectric seed layer and overlayer on carrier transport in epitaxial graphene. We introduce a novel seeding technique for depositing dielectrics by atomic layer deposition that utilizes direct deposition of high-κ seed layers and can lead to an increase in Hall mobility up to 70% from as-grown. Additionally, high-κ seeded dielectrics are shown to produce superior transistor performance relative to low-κ seeded dielectrics and the presence of heterogeneous seed/overlayer structures is found to be detrimental to transistor performance, reducing effective mobility by 30-40%. The direct deposition of high-purity oxide seed represents the first robust method for the deposition of uniform atomic layer deposited dielectrics on epitaxial graphene that improves carrier transport.

Original language	English (US)
Pages (from-to)	3601-3607
Number of pages	7
Journal	Nano letters
Volume	11
Issue number	9
DOIs	https://doi.org/10.1021/nl201358y
State	Published - Sep 14 2011

All Science Journal Classification (ASJC) codes

Bioengineering
General Chemistry
General Materials Science
Condensed Matter Physics
Mechanical Engineering

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10.1021/nl201358y

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title = "Enhanced transport and transistor performance with oxide seeded high-κ gate dielectrics on wafer-scale epitaxial graphene",

abstract = "We explore the effect of high-κ dielectric seed layer and overlayer on carrier transport in epitaxial graphene. We introduce a novel seeding technique for depositing dielectrics by atomic layer deposition that utilizes direct deposition of high-κ seed layers and can lead to an increase in Hall mobility up to 70% from as-grown. Additionally, high-κ seeded dielectrics are shown to produce superior transistor performance relative to low-κ seeded dielectrics and the presence of heterogeneous seed/overlayer structures is found to be detrimental to transistor performance, reducing effective mobility by 30-40%. The direct deposition of high-purity oxide seed represents the first robust method for the deposition of uniform atomic layer deposited dielectrics on epitaxial graphene that improves carrier transport.",

author = "Hollander, {Matthew J.} and Michael Labella and Hughes, {Zachary R.} and Michael Zhu and Trumbull, {Kathleen A.} and Randal Cavalero and Snyder, {David W.} and Xiaojun Wang and Euichul Hwang and Suman Datta and Robinson, {Joshua A.}",

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doi = "10.1021/nl201358y",

language = "English (US)",

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journal = "Nano letters",

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publisher = "American Chemical Society",

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TY - JOUR

T1 - Enhanced transport and transistor performance with oxide seeded high-κ gate dielectrics on wafer-scale epitaxial graphene

AU - Hollander, Matthew J.

AU - Labella, Michael

AU - Hughes, Zachary R.

AU - Zhu, Michael

AU - Trumbull, Kathleen A.

AU - Cavalero, Randal

AU - Snyder, David W.

AU - Wang, Xiaojun

AU - Hwang, Euichul

AU - Datta, Suman

AU - Robinson, Joshua A.

PY - 2011/9/14

Y1 - 2011/9/14

N2 - We explore the effect of high-κ dielectric seed layer and overlayer on carrier transport in epitaxial graphene. We introduce a novel seeding technique for depositing dielectrics by atomic layer deposition that utilizes direct deposition of high-κ seed layers and can lead to an increase in Hall mobility up to 70% from as-grown. Additionally, high-κ seeded dielectrics are shown to produce superior transistor performance relative to low-κ seeded dielectrics and the presence of heterogeneous seed/overlayer structures is found to be detrimental to transistor performance, reducing effective mobility by 30-40%. The direct deposition of high-purity oxide seed represents the first robust method for the deposition of uniform atomic layer deposited dielectrics on epitaxial graphene that improves carrier transport.

AB - We explore the effect of high-κ dielectric seed layer and overlayer on carrier transport in epitaxial graphene. We introduce a novel seeding technique for depositing dielectrics by atomic layer deposition that utilizes direct deposition of high-κ seed layers and can lead to an increase in Hall mobility up to 70% from as-grown. Additionally, high-κ seeded dielectrics are shown to produce superior transistor performance relative to low-κ seeded dielectrics and the presence of heterogeneous seed/overlayer structures is found to be detrimental to transistor performance, reducing effective mobility by 30-40%. The direct deposition of high-purity oxide seed represents the first robust method for the deposition of uniform atomic layer deposited dielectrics on epitaxial graphene that improves carrier transport.

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JO - Nano letters

JF - Nano letters

IS - 9

ER -

Enhanced transport and transistor performance with oxide seeded high-κ gate dielectrics on wafer-scale epitaxial graphene

Abstract

All Science Journal Classification (ASJC) codes

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