Synthesis and Properties of Non-Curing Graphene Thermal Interface Materials

TL;DR

This paper presents the synthesis of non-curing graphene-based thermal interface materials that outperform commercial pastes in thermal conductivity, highlighting a unique percolation behavior and potential for large-scale electronic cooling applications.

Contribution

It introduces a novel non-curing graphene thermal paste with superior thermal conductivity and analyzes its percolation behavior, contrasting it with curing epoxy-based materials.

Findings

Graphene thermal paste exhibits a thermal percolation threshold with sublinear conductivity dependence.

It outperforms commercial thermal pastes at ~27 vol% filler loading.

The study sheds light on thermal percolation mechanisms in non-curing polymer matrices.

Abstract

Development of the next generation thermal interface materials with high thermal conductivity is important for thermal management and packaging of electronic devices. We report on the synthesis and thermal conductivity measurements of non-curing thermal paste, i.e. grease, based on mineral oil with the mixture of graphene and few-layer graphene flakes as the fillers. It was found that graphene thermal paste exhibits a distinctive thermal percolation threshold with the thermal conductivity revealing a sublinear dependence on the filler loading. This behavior contrasts with the thermal conductivity of curing graphene thermal interface materials, based on epoxy, where super-linear dependence on the filler loading is observed. The performance of graphene thermal paste was benchmarked against top-of-the-line commercial thermal pastes. The obtained results show that non-curing graphene thermal interface materials outperforms the best commercial pastes in terms of thermal conductivity, at substantially lower filler concentration of ~ 27 vol%. The obtained results shed light on thermal percolation mechanism in non-curing polymeric matrices laden with quasi-two-dimensional fillers. Considering recent progress in graphene production via liquid phase exfoliation and oxide reduction, we argue that our results open a pathway for large-scale industrial application of graphene in thermal management of electronics.