Direct synthesis of vertical graphene nanowalls on glass substrate for thermal management

Nan Zhang; Jiurong Li; Zhiduo Liu; Siwei Yang; Anli Xu; Da Chen; Qinglei Guo; Gang Wang

doi:10.1088/2053-1591/aacb59

Direct synthesis of vertical graphene nanowalls on glass substrate for thermal management

Nan Zhang, Jiurong Li, Zhiduo Liu, Siwei Yang, Anli Xu, Da Chen^*, Qinglei Guo, Gang Wang

^*Corresponding author for this work

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

18 Citations (Scopus)

Abstract

Vertical few layered graphene (VG) nanoflakes were directly synthesized on traditional glass substrate by the plasma-assisted chemical vapor deposition, where the extremely low growing temperature (<560 °C) and short time (<30 min) were involved. The VG microstructure could be well-controlled by tuning the plasma power, growth time and growth temperature. Raman, TEM, and SEM were used to determine the quality and single size of the VG. Because of the unique three-dimensional structure with high surface area, the VG network can provide superior thermal management capabilities, which has been demonstrated by the scalable frost removal. We believed that this hybrid system consisting of vertical graphene nanowalls and glass substrates has great potentials for future transparent 'green-warmth' constructions.

Original language	English
Article number	065606
Journal	Materials Research Express
Volume	5
Issue number	6
DOIs	https://doi.org/10.1088/2053-1591/aacb59
Publication status	Published - Jun 2018
Externally published	Yes

Keywords

graphene nanowalls
plasma-assisted chemical vapor deposition
thermal management

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10.1088/2053-1591/aacb59

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title = "Direct synthesis of vertical graphene nanowalls on glass substrate for thermal management",

abstract = "Vertical few layered graphene (VG) nanoflakes were directly synthesized on traditional glass substrate by the plasma-assisted chemical vapor deposition, where the extremely low growing temperature (<560 °C) and short time (<30 min) were involved. The VG microstructure could be well-controlled by tuning the plasma power, growth time and growth temperature. Raman, TEM, and SEM were used to determine the quality and single size of the VG. Because of the unique three-dimensional structure with high surface area, the VG network can provide superior thermal management capabilities, which has been demonstrated by the scalable frost removal. We believed that this hybrid system consisting of vertical graphene nanowalls and glass substrates has great potentials for future transparent 'green-warmth' constructions.",

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TY - JOUR

T1 - Direct synthesis of vertical graphene nanowalls on glass substrate for thermal management

AU - Zhang, Nan

AU - Li, Jiurong

AU - Liu, Zhiduo

AU - Yang, Siwei

AU - Xu, Anli

AU - Chen, Da

AU - Guo, Qinglei

AU - Wang, Gang

PY - 2018/6

Y1 - 2018/6

N2 - Vertical few layered graphene (VG) nanoflakes were directly synthesized on traditional glass substrate by the plasma-assisted chemical vapor deposition, where the extremely low growing temperature (<560 °C) and short time (<30 min) were involved. The VG microstructure could be well-controlled by tuning the plasma power, growth time and growth temperature. Raman, TEM, and SEM were used to determine the quality and single size of the VG. Because of the unique three-dimensional structure with high surface area, the VG network can provide superior thermal management capabilities, which has been demonstrated by the scalable frost removal. We believed that this hybrid system consisting of vertical graphene nanowalls and glass substrates has great potentials for future transparent 'green-warmth' constructions.

AB - Vertical few layered graphene (VG) nanoflakes were directly synthesized on traditional glass substrate by the plasma-assisted chemical vapor deposition, where the extremely low growing temperature (<560 °C) and short time (<30 min) were involved. The VG microstructure could be well-controlled by tuning the plasma power, growth time and growth temperature. Raman, TEM, and SEM were used to determine the quality and single size of the VG. Because of the unique three-dimensional structure with high surface area, the VG network can provide superior thermal management capabilities, which has been demonstrated by the scalable frost removal. We believed that this hybrid system consisting of vertical graphene nanowalls and glass substrates has great potentials for future transparent 'green-warmth' constructions.

KW - graphene nanowalls

KW - plasma-assisted chemical vapor deposition

KW - thermal management

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Direct synthesis of vertical graphene nanowalls on glass substrate for thermal management

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Keywords

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