Yixin Han#, Xuetao Shi#, Xutong Yang, Yongqiang Guo, Junliang Zhang, Jie Kong and Junwei Gu*. Enhanced thermal conductivities of epoxy nanocomposites via incorporating in-situ fabricated hetero-structured SiC-BNNS fillers. Composites Science and Technology, 2020, 187: 107944. 2018IF=6.309. (1區(qū)/Top期刊:復(fù)合材料領(lǐng)域頂尖期刊).
Abstract: Novel hetero-structured silicon carbide-boron nitride nanosheets (SiC-BNNS) by sol-gel and in-situ growth method were performed as thermally conductive & insulating fillers, and the SiC-BNNS/epoxy thermally conductive nanocomposites were then prepared by blending-casting approach. Synthesized hetero-structured SiC-BNNS fillers have synergistic improvement effects on the thermal conductivities of the SiC-BNNS/epoxy nanocomposites. When the amount of hetero-structured SiC-BNNS fillers is 20?wt% (SiC-BNNS, 1/1, w/w), the thermal conductivity coefficient (λ) value of the SiC-BNNS/epoxy nanocomposites (0.89?W/mK) is 4.1 times that of pure epoxy resin (0.22?W/mK), and 2.1, 1.4, and 1.7 times of SiC/epoxy (0.43?W/mK), BNNS/epoxy (0.62?W/mK), and (SiC/BNNS)/epoxy thermally conductive nanocomposites (0.52?W/mK) with the same amount of fillers (20?wt% single BNNS, SiC, or SiC/BNNS hybrid fillers), respectively. Meantime, the obtained (SiC-BNNS)/epoxy thermally conductive nanocomposites also demonstrate favorable electrical insulating properties, and the breakdown strength, volume resistivity as well as surface resistivity is 22.1?kV/mm, 2.32?×?1015?Ω?cm, and 1.26?×?1015?Ω?cm, respectively.
