Preparation and thermal properties of polyacrylonitrile-based carbon fiber–silicon carbide core–shell hybrid

Abstract A polyacrylonitrile (PAN)-based carbon fiber–silicon carbide core–shell hybrid (SiC/PAN-CF) was prepared by carbothermal reduction of SiO 2 /PAN-CF, which was obtained by dip coating a SiO 2 sol on the surface of PAN-CF. The surface of the PAN-CF was uniformly covered with the SiC, and the decomposition temperature of SiC/PAN-CF was higher than that of the uncoated PAN-CF. In addition, the thermal conductivity of epoxy composites consisting of PAN-CF or SiC/PAN-CF was measured using a laser flash method. At a 80 wt% filler loading, the thermal conductivity of SiC/PAN-CF-epoxy composite was found to be 0.750 W/mK, which is 2 times higher than that of the PAN-CF-epoxy composite and approximately 3.5 times greater than that of unmodified epoxy resin. Furthermore, the thermal conductivity of SiC/PAN-CF-epoxy composite increased with increasing carbothermal reduction time. This increased thermal conductivity is due to improving the specific surface area and wettability with epoxy matrix, thus resulting in an improved the interfacial adhesion with epoxy matrix.