RGO and Three-Dimensional Graphene Networks Co-modified TIMs with High Performances

RGO and Three-Dimensional Graphene Networks Co-modified TIMs with High Performances

Abstract With the development of microelectronic devices, the insufficient heat dissipation ability becomes one of the major bottlenecks for further miniaturization. Although graphene-assisted epoxy resin (ER) display promising potential to enhance the thermal performances, some limitations of the r...

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Main Authors: Tang Bo, Wang Zhengwei, Weiqiu Huang, Li Sen, Ma Tingting, Yu Haogang, Li Xufei
Format: Article
Language:English
Published: SpringerOpen 2017-09-01
Series:Nanoscale Research Letters
Subjects:
Thermal Interface Materials
Graphene
Thermal Boundary Resistance
Online Access:http://link.springer.com/article/10.1186/s11671-017-2298-z
id doaj-252d15735dc6460dbae04216976e35ea
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spelling doaj-252d15735dc6460dbae04216976e35ea2020-11-25T01:02:07ZengSpringerOpenNanoscale Research Letters1931-75731556-276X2017-09-011211710.1186/s11671-017-2298-zRGO and Three-Dimensional Graphene Networks Co-modified TIMs with High PerformancesTang Bo0Wang Zhengwei1Weiqiu Huang2Li Sen3Ma Tingting4Yu Haogang5Li Xufei6School of Petroleum Engineering, Changzhou UniversitySchool of Petroleum Engineering, Changzhou UniversitySchool of Petroleum Engineering, Changzhou UniversitySchool of Petroleum Engineering, Changzhou UniversitySchool of Petroleum Engineering, Changzhou UniversitySchool of Petroleum Engineering, Changzhou UniversitySchool of Petroleum Engineering, Changzhou UniversityAbstract With the development of microelectronic devices, the insufficient heat dissipation ability becomes one of the major bottlenecks for further miniaturization. Although graphene-assisted epoxy resin (ER) display promising potential to enhance the thermal performances, some limitations of the reduced graphene oxide (RGO) nanosheets and three-dimensional graphene networks (3DGNs) hinder the further improvement of the resulting thermal interface materials (TIMs). In this study, both the RGO nanosheets and 3DGNs are adopted as co-modifiers to improve the thermal conductivity of the ER. The 3DGNs provide a fast transport network for phonon, while the presence of RGO nanosheets enhances the heat transport at the interface between the graphene basal plane and the ER. The synergy of these two modifiers is achieved by selecting a proper proportion and an optimized reduction degree of the RGO nanosheets. Moreover, both the high stability of the thermal conductivity and well mechanical properties of the resulting TIM indicate the potential application prospect in the practical field.http://link.springer.com/article/10.1186/s11671-017-2298-zThermal Interface MaterialsGrapheneThermal Boundary Resistance
collection DOAJ
language English
format Article
sources DOAJ
author Tang Bo
Wang Zhengwei
Weiqiu Huang
Li Sen
Ma Tingting
Yu Haogang
Li Xufei
spellingShingle Tang Bo
Wang Zhengwei
Weiqiu Huang
Li Sen
Ma Tingting
Yu Haogang
Li Xufei
RGO and Three-Dimensional Graphene Networks Co-modified TIMs with High Performances
Nanoscale Research Letters
Thermal Interface Materials
Graphene
Thermal Boundary Resistance
author_facet Tang Bo
Wang Zhengwei
Weiqiu Huang
Li Sen
Ma Tingting
Yu Haogang
Li Xufei
author_sort Tang Bo
title RGO and Three-Dimensional Graphene Networks Co-modified TIMs with High Performances
title_short RGO and Three-Dimensional Graphene Networks Co-modified TIMs with High Performances
title_full RGO and Three-Dimensional Graphene Networks Co-modified TIMs with High Performances
title_fullStr RGO and Three-Dimensional Graphene Networks Co-modified TIMs with High Performances
title_full_unstemmed RGO and Three-Dimensional Graphene Networks Co-modified TIMs with High Performances
title_sort rgo and three-dimensional graphene networks co-modified tims with high performances
publisher SpringerOpen
series Nanoscale Research Letters
issn 1931-7573
1556-276X
publishDate 2017-09-01
description Abstract With the development of microelectronic devices, the insufficient heat dissipation ability becomes one of the major bottlenecks for further miniaturization. Although graphene-assisted epoxy resin (ER) display promising potential to enhance the thermal performances, some limitations of the reduced graphene oxide (RGO) nanosheets and three-dimensional graphene networks (3DGNs) hinder the further improvement of the resulting thermal interface materials (TIMs). In this study, both the RGO nanosheets and 3DGNs are adopted as co-modifiers to improve the thermal conductivity of the ER. The 3DGNs provide a fast transport network for phonon, while the presence of RGO nanosheets enhances the heat transport at the interface between the graphene basal plane and the ER. The synergy of these two modifiers is achieved by selecting a proper proportion and an optimized reduction degree of the RGO nanosheets. Moreover, both the high stability of the thermal conductivity and well mechanical properties of the resulting TIM indicate the potential application prospect in the practical field.
topic Thermal Interface Materials
Graphene
Thermal Boundary Resistance
url http://link.springer.com/article/10.1186/s11671-017-2298-z
work_keys_str_mv AT tangbo rgoandthreedimensionalgraphenenetworkscomodifiedtimswithhighperformances
AT wangzhengwei rgoandthreedimensionalgraphenenetworkscomodifiedtimswithhighperformances
AT weiqiuhuang rgoandthreedimensionalgraphenenetworkscomodifiedtimswithhighperformances
AT lisen rgoandthreedimensionalgraphenenetworkscomodifiedtimswithhighperformances
AT matingting rgoandthreedimensionalgraphenenetworkscomodifiedtimswithhighperformances
AT yuhaogang rgoandthreedimensionalgraphenenetworkscomodifiedtimswithhighperformances
AT lixufei rgoandthreedimensionalgraphenenetworkscomodifiedtimswithhighperformances
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