The nanocomposite combines one-dimensional polymer nanofibers and two-dimensional boron nitride nanosheets. The nanofibers reinforce the self-assembling material while the “white graphene” nanosheets provide a thermally conductive network that allows it to withstand the heat that breaks down common dielectrics, the polarized insulators in batteries and other devices that separate positive and negative electrodes.
Research scientist M.M. Rahman and postdoctoral researcher Anand Puthirath of the Ajayan lab led the study to meet the challenge posed by next-generation electronics: Dielectrics must be thin, tough, flexible and able to withstand harsh environments.
“Ceramic is a very good dielectric, but it is mechanically brittle,” Rahman said of the common material. “On the other hand, polymer is a good dielectric with good mechanical properties, but its thermal tolerance is very low.”
Boron nitride is an electrical insulator, but happily disperses heat, he said. “When we combined the polymer nanofiber with boron nitride, we got a material that’s mechanically exceptional, and thermally and chemically very stable,” Rahman said.
The 12-to-15-micron-thick material acts as an effective heat sink up to 250 degrees Celsius (482 degrees Fahrenheit), according to the researchers. Tests showed the polymer nanofibers-boron nitride combination dispersed heat four times better than the polymer alone.
In its simplest form, a single layer of polyaramid nanofibers binds via van der Waals forces to a sprinkling of boron nitride flakes, 10% by weight of the final product. The flakes are just dense enough to form a heat-dissipating network that still allows the composite to retain its flexibility, and even foldability, while maintaining its robustness. Layering polyaramid and boron nitride can make the material thicker while still retaining flexibility, according to the researchers.
“The 1D polyaramid nanofiber has many interesting properties except thermal conductivity,” Rahman said. “And boron nitride is a very interesting 2D material right now. They both have different independent properties, but when they are together, they make something very unique.”
Rahman said the material is scalable and should be easy to incorporate into manufacturing.
Co-authors of the paper are Rice academic visitors Aparna Adumbumkulath and Fanshu Yuan, alumnus Thierry Tsafack, graduate students Morgan Barnes, Zixing Wang, Sandhya Susarla, Seyed Mohammad Sajadi, Devashish Salpekar and Hossein Robatjazi, research scientist Ganguli Babu and Rafael Verduzco, an associate professor of chemical and biomolecular engineering and of materials science and nanoengineering; Sampath Kommandur and Shannon Yee of the Georgia Institute of Technology; and Kazuki Nomoto, S.M. Islam and Huili Xing of Cornell University. Ajayan is chair of Rice’s Department of Materials Science and NanoEngineering, the Benjamin M. and Mary Greenwood Anderson Professor in Engineering and a professor of chemistry.
The Army Research Laboratory funded the research.