Graphene‐Based Devices for Thermal Energy Conversion and Utilization

Thermal energy conversion and utilization of integrated circuits is a very important research topic. Graphene is a new 2D material with superior electrical, mechanical, thermal, and optical properties, which is expected to continue Moore's law and make breakthroughs in the direction of “More th...

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Bibliographic Details
Published in:Advanced functional materials 2020-02, Vol.30 (8), p.n/a
Main Authors: Li, Yu‐Tao, Tian, Ye, Sun, Meng‐Xing, Tu, Tao, Ju, Zhen‐Yi, Gou, Guang‐Yang, Zhao, Yun‐Fei, Yan, Zhao‐Yi, Wu, Fan, Xie, Dan, Tian, He, Yang, Yi, Ren, Tian‐Ling
Format: Article
Language:English
Subjects:
Devices
Electrical resistivity
Energy conversion
Graphene
graphene production
Integrated circuits
Materials science
Moore's law
Nanoelectronics
Nanotechnology devices
Optical coupling
Optical properties
Thermal conductivity
thermal devices
Thermal energy
Thermal utilization
thermoacoustic coupling
thermoelectric coupling
thermo‐optical coupling
Two dimensional materials
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Summary:Thermal energy conversion and utilization of integrated circuits is a very important research topic. Graphene is a new 2D material with superior electrical, mechanical, thermal, and optical properties, which is expected to continue Moore's law and make breakthroughs in the direction of “More than Moore.” Graphene‐based functionalized devices are applied in various aspects, including breakthroughs in thermal devices, due to their high thermal conductivity and thermal rectification. According to the coupling of different physical quantities, graphene‐based thermal devices can be divided into four categories: uncoupled thermal devices, thermoacoustic coupling devices, thermoelectric coupling devices, and thermo‐optical coupling devices. The structure, working mechanism, and performance of these devices are discussed, as well as the coupling methods of physical quantities. Moreover, scale‐up production of graphene and prospect for future graphene‐based thermal devices are summarized. In‐depth study of the development tendency of these graphene‐based thermal devices is expected to contribute to the development of new high‐performance thermal nanoelectronic devices in the future. Graphene‐based thermal devices can be divided into four categories: uncoupled thermal devices, thermoacoustic coupling devices, thermoelectric coupling devices, and thermo‐optical coupling devices. The structure, working mechanism, and performance of these devices are discussed, as well as the coupling method of physical quantities. Finally, graphene production and graphene‐based thermal device prospects are summarized.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.201903888