Litcius/Paper detail

Amino multi-walled carbon nanotubes further improve the thermal conductivity of boron nitride/liquid crystal epoxy resin composites

Tengfei Qin, H. Wang, Jing He, Qiqi Qu, Yunsheng Da, Xiaoyong Tian

2020eXPRESS Polymer Letters18 citationsDOIOpen Access PDF

Abstract

In this work, we introduced highly thermally conductive and fibrous amino multi-walled carbon nanotubes (MCNT-NH 2 ) into hexagonal boron nitride/liquid crystal epoxy resin (h-BN/LCER) composites to improve the thermal conductivity of the composites. First, we prepared hexagonal boron nitride@amino multi-walled carbon nanotubes (h-BN@MCNT-NH 2 ) hybrid fillers. Then, the amino group in the hybrid filler participated in the curing process of the epoxy resin to prepare hexagonal boron nitride@amino multi-walled carbon nanotubes/liquid crystal epoxy resin (h-BN@MCNT-NH 2 /LCER) composites. Subsequently, its thermal conductivity was tested and analyzed using the Agari's model and microstructure of the composites, and we can come to conclude that the thermal conductivity of h-BN@MCNT-NH 2 /LCER composites is higher than that of h-BN/LCER at the same filler content. The main reason is that the addition of MCNT-NH 2 plays a role in increasing the thermal conduction path of h-BN/LCER composites and decreasing the large interface thermal resistance of fillers and resin matrix. Finally, the usability and thermal conductivity of h-BN@MCNT-NH 2 /LECR composites were verified by light-emitting diode (LED) lamps. The temperature of LED lamp using 50% h-BN@MCNT-NH 2 /LCER composites was eventually stabilized at 27.7 C, it is expected that 50% h-BN@MCNT-NH 2 /LCER composites will be used in LED electronic products.

Topics & Concepts

Materials scienceEpoxyComposite materialBoron nitrideCarbon nanotubeThermal conductivityLiquid crystalThermalBoronOrganic chemistryMeteorologyOptoelectronicsPhysicsChemistryThermal properties of materialsSynthesis and properties of polymersTribology and Wear Analysis