Energy dissipation in graphene field-effect transistors

Marcus Freitag; Mathias Steiner; Yves Martin; Vasili Perebeinos; Zhihong Chen; James C. Tsang; Phaedon Avouris

doi:10.1021/nl803883h

Energy dissipation in graphene field-effect transistors

Marcus Freitag
, Mathias Steiner
, Yves Martin
, Vasili Perebeinos
, Zhihong Chen
, James C. Tsang
, Phaedon Avouris

Department of Electrical Engineering

IBM

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

379 Scopus citations

Abstract

We measure the temperature distribution in a biased single-layer graphene transistor using Raman scattering microscopy of the 2D-phonon band. Peak operating temperatures of 1050 K are reached in the middle of the graphene sheet at 210 kW cm ^-2 of dissipated electric power. The metallic contacts act as heat sinks, but not in a dominant fashion. To explain the observed temperature profile and heating rate, we have to include heat flow from the graphene to the gate oxide underneath, especially at elevated temperatures, where the graphene thermal conductivity is lowered due to umklapp scattering. Velocity saturation due to phonons with about 50-60 meV energy is inferred from the measured charge density via shifts in the Raman G-phonon band, suggesting that remote scattering (through field coupling) by substrate polar surface phonons increases the energy transfer to the substrate and at the same time limits the high-bias electronic conduction of graphene.

Original language	English
Pages (from-to)	1883-1888
Number of pages	6
Journal	Nano Letters
Volume	9
Issue number	5
DOIs	https://doi.org/10.1021/nl803883h
State	Published - May 13 2009

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10.1021/nl803883h

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title = "Energy dissipation in graphene field-effect transistors",

abstract = "We measure the temperature distribution in a biased single-layer graphene transistor using Raman scattering microscopy of the 2D-phonon band. Peak operating temperatures of 1050 K are reached in the middle of the graphene sheet at 210 kW cm -2 of dissipated electric power. The metallic contacts act as heat sinks, but not in a dominant fashion. To explain the observed temperature profile and heating rate, we have to include heat flow from the graphene to the gate oxide underneath, especially at elevated temperatures, where the graphene thermal conductivity is lowered due to umklapp scattering. Velocity saturation due to phonons with about 50-60 meV energy is inferred from the measured charge density via shifts in the Raman G-phonon band, suggesting that remote scattering (through field coupling) by substrate polar surface phonons increases the energy transfer to the substrate and at the same time limits the high-bias electronic conduction of graphene.",

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AU - Freitag, Marcus

AU - Steiner, Mathias

AU - Martin, Yves

AU - Perebeinos, Vasili

AU - Chen, Zhihong

AU - Tsang, James C.

AU - Avouris, Phaedon

PY - 2009/5/13

Y1 - 2009/5/13

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AB - We measure the temperature distribution in a biased single-layer graphene transistor using Raman scattering microscopy of the 2D-phonon band. Peak operating temperatures of 1050 K are reached in the middle of the graphene sheet at 210 kW cm -2 of dissipated electric power. The metallic contacts act as heat sinks, but not in a dominant fashion. To explain the observed temperature profile and heating rate, we have to include heat flow from the graphene to the gate oxide underneath, especially at elevated temperatures, where the graphene thermal conductivity is lowered due to umklapp scattering. Velocity saturation due to phonons with about 50-60 meV energy is inferred from the measured charge density via shifts in the Raman G-phonon band, suggesting that remote scattering (through field coupling) by substrate polar surface phonons increases the energy transfer to the substrate and at the same time limits the high-bias electronic conduction of graphene.

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Energy dissipation in graphene field-effect transistors

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