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Author Wang, Haidong ♦ Kurata, Kosaku ♦ Fukunaga, Takanobu ♦ Takamatsu, Hiroshi ♦ Ago, Hiroki ♦ Zhang, Xing ♦ Ikuta, Tatsuya ♦ Takahashi, Koji ♦ Nishiyama, Takashi ♦ Takata, Yasuyuki
Source United States Department of Energy Office of Scientific and Technical Information
Content type Text
Language English
Subject Keyword CLASSICAL AND QUANTUM MECHANICS, GENERAL PHYSICS ♦ CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY ♦ CARRIERS ♦ ELECTRONIC EQUIPMENT ♦ ELECTRONS ♦ GRAPHENE ♦ HEAT ♦ HEAT TRANSFER ♦ LAYERS ♦ PHONONS ♦ SENSORS ♦ SUBSTRATES ♦ TEMPERATURE RANGE 0273-0400 K ♦ THERMAL CONDUCTIVITY ♦ WAVELENGTHS ♦ WIEDEMANN-FRANZ LAW
Abstract We measured both in-plane electrical and thermal properties of the same suspended monolayer graphene using a novel T-type sensor method. At room temperature, the values are about 240 000 Ω{sup −1} m{sup −1} and 2100 W m{sup −1} K{sup −1} for the electrical and thermal conductivities, respectively. Based on the Wiedemann-Franz law, the electrons have negligible contribution to the thermal conductivity of graphene, while the in-plane LA and TA modes phonons are the dominant heat carriers. In monolayer graphene, the absence of layer-layer and layer-substrate interactions enhances the contribution of long wave-length phonons to the heat transport and increases the thermal conductivity accordingly. The reported method and experimental data of suspended monolayer graphene are useful for understanding the basic physics and designing the future graphene electronic devices.
ISSN 00218979
Educational Use Research
Learning Resource Type Article
Publisher Date 2016-06-28
Publisher Place United States
Journal Journal of Applied Physics
Volume Number 119
Issue Number 24


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