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A Spiral Graphene Framework Containing Highly Ordered Graphene Microtubes for Polymer Composites with Superior <scp>Through‐Plane</scp> Thermal Conductivity

Jinrui Gong, Xue Tan, Qilong Yuan, Zhiduo Liu, Junfeng Ying, Le Lv, Qingwei Yan, Wubo Chu, Xue Chen, Jinhong Yu, Kazuhito Nishimura, Nan Jiang, Cheng‐Te Lin, Wen Dai

2021Chinese Journal of Chemistry20 citationsDOI

Abstract

Comprehensive Summary As the power density of electronic devices increases, there has been an urgent demand to develop highly conductive polymer composites to address the accompanying thermal management issues. Due to the ultra‐high intrinsic thermal conductivity, graphene is considered a very promising filler to improve the thermal conductivity of polymers. However, graphene‐based polymer composites prepared by the conventional mixing method generally have limited thermal conductivity, even under high graphene loading, due to the failure to construct efficient heat transfer pathways in the polymer matrix. Here, a spiral graphene framework (SGF) containing continuous and highly ordered graphene microtubes was developed based on a modified CVD method. After embedding into the epoxy (EP) matrix, the graphene microtubes can act as efficient heat pathways, endowing the SGF/EP composites with a high through‐plane thermal conductivity of 1.35 W·m −1 ·K −1 at an ultralow graphene loading of 0.86 wt%. This result gives a thermal conductivity enhancement per 1 wt% filler loading of 710%, significantly outperforming various graphene structures as fillers. In addition, we demonstrated the practical application of the SGF/EP composite as a thermal interface material for efficient thermal management of the light‐emitting diode (LED).

Topics & Concepts

GrapheneThermal conductivityComposite materialMaterials scienceGraphene foamEpoxyPolymerComposite numberGraphene oxide paperNanotechnologyThermal properties of materialsGraphene research and applicationsThermal Radiation and Cooling Technologies