Construction of 3D interconnected boron nitride/carbon nanofiber hybrid network within polymer composite for thermal conductivity improvement

With the increasing power density and integration of electronic devices, polymeric composites with high thermal conductivity (TC) are in urgent demand for solving heat accumulation issues. However, the di-rect introduction of inorganic fillers into a polymer matrix at low filler content usually leads to low TC enhancement. In this work, an interconnected three-dimensional (3D) polysulfone/hexagonal boron nitride-carbon nanofiber (PSF/BN-CNF) skeleton was prepared via the salt templated method to address this issue. After embedding into the epoxy (EP), the EP/PSF/BN-CNF composite presents a high TC of 2.18 W m -1 K -1 at a low filler loading of 28.61 wt%, corresponding to a TC enhancement of 990% compared to the neat epoxy. The enhanced TC is mainly attributed to the fabricated 3D interconnected structure and the efficient synergistic effect of BN and CNF. In addition, the TC of the epoxy composites can be further increased to 2.85 W m -1 K -1 at the same filler loading through a post-heat treatment of the PSF/BN-CNF skeletons. After carbonization at 1500 degrees C, the adhesive PSF was converted into carbonaceous layers, which could serve as a thermally conductive glue to connect the filler network, further decreasing the interfacial thermal resistance and promoting phonon transport. Besides, the good heat dissipation performance of the EP/C/BN-CNF composites was directly confirmed by thermal infrared imaging, indicating a bright and broad application in the thermal management of modern electronics and energy fields.(c) 2023 Published by Elsevier Ltd on behalf of The editorial office of Journal of Materials Science & Technology.

Automated summary

Polymeric composites with high thermal conductivity are needed for solving heat accumulation issues. In this study, an interconnected three-dimensional polysulfone/hexagonal boron nitride-carbon nanofiber skeleton was prepared and embedded into epoxy. The resulting composite showed a high thermal conductivity of 2.18 W m -1 K -1 at a low filler loading, with a 990% enhancement compared to neat epoxy. The enhanced thermal conductivity was attributed to the 3D structure and synergistic effect of boron nitride and carbon nanofiber. The thermal conductivity of the composite can be further increased through post-heat treatment, resulting in potential applications in thermal management.