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Effects of high-temperature thermal reduction on thermal conductivity of reduced graphene oxide polymer composites

Yun Seon Lee, Nam Ryeol Kim, Sang Ki Park, Yong‐Il Ko, Yunjae Shin, Beomjoo Yang, Cheol‐Min Yang

2023Applied Surface Science33 citationsDOIOpen Access PDF

Abstract

The graphitic crystalline structure of reduced graphene oxide (rGO) can be improved by high-temperature thermal reduction at various heat-treatment temperatures ranging from 1000 to 2500 °C. The crystallinity significantly increased with increasing heat-treatment temperature. The electrical conductivities of the rGOs heat-treated at 2000 and 2500 °C (h-rGO-2000 and h-rGO-2500, respectively) were similar to those of commercial graphite. The isotropic thermal conductivity of rGO/epoxy composite with 10 wt% h-rGO-2500 (2.56 W/mK) is 11.6 times higher than that of pristine rGO (p-rGO; 0.22 W/mK) and significantly superior to those of epoxy composites with commercial graphite (0.82 W/mK) and mesophase pitch-based carbon fibers (MPCFs; 1.29 W/mK). Moreover, owing to the synergistic effect operating in the MPCF–h-rGO hybrid filler in epoxy composites, this combination of fillers increases the thermal conductivity to a greater extent than the MPCF–p-rGO hybrid filler. Optimum synergistic effects on the isotropic and in-plane thermal conductivities were achieved with an MPCF:h-rGO-2000 weight ratio of 49:1 (17.93 W/mK, 1.85 times higher than 9.69 W/mK for MPCF–p-rGO). Finally, a machine learning method that could predict and optimize the properties of rGOs based on their HT temperatures and material compositions was developed.

Topics & Concepts

Materials scienceGrapheneComposite materialThermal conductivityEpoxyGraphiteOxideCrystallinityComposite numberGraphite oxideFiller (materials)NanotechnologyMetallurgyThermal properties of materialsGraphene research and applicationsCarbon Nanotubes in Composites