Graphene gate electrode for MOS structure-based electronic devices

Jong Kyung Park; Seung Min Song; Jeong Hun Mun; Byung Jin Cho

doi:10.1021/nl202983x

Graphene gate electrode for MOS structure-based electronic devices

Jong Kyung Park
, Seung Min Song
, Jeong Hun Mun
, Byung Jin Cho

Dept. of Semiconductor Engineering

Korea Advanced Institute of Science and Technology

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

70 Scopus citations

Abstract

We demonstrate that the use of a monolayer graphene as a gate electrode on top of a high-κ gate dielectric eliminates mechanical-stress-induced-gate dielectric degradation, resulting in a quantum leap of gate dielectric reliability. The high work function of hole-doped graphene also helps reduce the quantum mechanical tunneling current from the gate electrode. This concept is applied to nonvolatile Flash memory devices, whose performance is critically affected by the quality of the gate dielectric. Charge-trap flash (CTF) memory with a graphene gate electrode shows superior data retention and program/erase performance that current CTF devices cannot achieve. The findings of this study can lead to new applications of graphene, not only for Flash memory devices but also for other high-performance and mass-producible electronic devices based on MOS structure which is the mainstream of the electronic device industry.

Original language	English
Pages (from-to)	5383-5386
Number of pages	4
Journal	Nano Letters
Volume	11
Issue number	12
DOIs	https://doi.org/10.1021/nl202983x
State	Published - 14 Dec 2011

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 9 Industry, Innovation, and Infrastructure

Keywords

charge-trap flash (CTF) memory
gate dielectric
Graphene
graphene gate electrode
mechanical stress
tunneling current

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10.1021/nl202983x

Cite this

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title = "Graphene gate electrode for MOS structure-based electronic devices",

abstract = "We demonstrate that the use of a monolayer graphene as a gate electrode on top of a high-κ gate dielectric eliminates mechanical-stress-induced-gate dielectric degradation, resulting in a quantum leap of gate dielectric reliability. The high work function of hole-doped graphene also helps reduce the quantum mechanical tunneling current from the gate electrode. This concept is applied to nonvolatile Flash memory devices, whose performance is critically affected by the quality of the gate dielectric. Charge-trap flash (CTF) memory with a graphene gate electrode shows superior data retention and program/erase performance that current CTF devices cannot achieve. The findings of this study can lead to new applications of graphene, not only for Flash memory devices but also for other high-performance and mass-producible electronic devices based on MOS structure which is the mainstream of the electronic device industry.",

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doi = "10.1021/nl202983x",

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T1 - Graphene gate electrode for MOS structure-based electronic devices

AU - Park, Jong Kyung

AU - Song, Seung Min

AU - Mun, Jeong Hun

AU - Cho, Byung Jin

PY - 2011/12/14

Y1 - 2011/12/14

N2 - We demonstrate that the use of a monolayer graphene as a gate electrode on top of a high-κ gate dielectric eliminates mechanical-stress-induced-gate dielectric degradation, resulting in a quantum leap of gate dielectric reliability. The high work function of hole-doped graphene also helps reduce the quantum mechanical tunneling current from the gate electrode. This concept is applied to nonvolatile Flash memory devices, whose performance is critically affected by the quality of the gate dielectric. Charge-trap flash (CTF) memory with a graphene gate electrode shows superior data retention and program/erase performance that current CTF devices cannot achieve. The findings of this study can lead to new applications of graphene, not only for Flash memory devices but also for other high-performance and mass-producible electronic devices based on MOS structure which is the mainstream of the electronic device industry.

AB - We demonstrate that the use of a monolayer graphene as a gate electrode on top of a high-κ gate dielectric eliminates mechanical-stress-induced-gate dielectric degradation, resulting in a quantum leap of gate dielectric reliability. The high work function of hole-doped graphene also helps reduce the quantum mechanical tunneling current from the gate electrode. This concept is applied to nonvolatile Flash memory devices, whose performance is critically affected by the quality of the gate dielectric. Charge-trap flash (CTF) memory with a graphene gate electrode shows superior data retention and program/erase performance that current CTF devices cannot achieve. The findings of this study can lead to new applications of graphene, not only for Flash memory devices but also for other high-performance and mass-producible electronic devices based on MOS structure which is the mainstream of the electronic device industry.

KW - charge-trap flash (CTF) memory

KW - gate dielectric

KW - Graphene

KW - graphene gate electrode

KW - mechanical stress

KW - tunneling current

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U2 - 10.1021/nl202983x

DO - 10.1021/nl202983x

M3 - Article

AN - SCOPUS:83655164347

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SP - 5383

EP - 5386

JO - Nano Letters

JF - Nano Letters

IS - 12

ER -

Graphene gate electrode for MOS structure-based electronic devices

Abstract

UN SDGs

Keywords

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