posted on 2016-10-27, 00:00authored byYimin Yao, Xiaoliang Zeng, Guiran Pan, Jiajia Sun, Jiantao Hu, Yun Huang, Rong Sun, Jian-Bin Xu, Ching-Ping Wong
Polymer
composites with high thermal conductivity have attracted much attention,
along with the rapid development of electronic devices toward higher
speed and better performance. However, high interfacial thermal resistance
between fillers and matrix or between fillers and fillers has been
one of the primary bottlenecks for the effective thermal conduction
in polymer composites. Herein, we report on engineering interfacial
structure of silicon carbide nanowire/cellulose microcrystal paper
by generating silver nanostructures. We show that silver nanoparticle-deposited
silicon carbide nanowires as fillers can effectively enhance the thermal
conductivity of the matrix. The in-plane thermal conductivity of the
resultant composite paper reaches as high as 34.0 W/m K, which is
one order magnitude higher than that of conventional polymer composites.
Fitting the measured thermal conductivity with theoretical models
qualitatively demonstrates that silver nanoparticles bring the lower
interfacial thermal resistances both at silicon carbide nanowire/cellulose
microcrystal and silicon carbide nanowire/silicon carbide nanowire
interfaces. This interfacial engineering approach provides a powerful
tool for sophisticated fabrication of high-performance thermal-management
materials.