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Abstract
Nylon 6,6 micro- and nano-silica composites were prepared by melt processing using a twin-screw extruder. Three nanocomposites containing 4, 8, and 12 wt.% of nanosilica were prepared. In order to compare the effect of size, a microcomposite containing 4 wt.% of micron-size silica was also prepared. The effects of particle type (micro- and nano-size) on the dynamic thermomechanical and rheological properties, morphology, and flame resistance of the composites were examined. The dynamic thermomechanical properties (DMTA), scanning electron microscopy (SEM), transmission electron microscopy (TEM), dynamic rheometry, thermogravimetry analysis (TGA), and limiting oxygen index (LOI) data are reported. The particles were observed to be dispersed uniformly, but with a different level of coalescence, by means of SEM and TEM. The DMTA results showed that the damping factor peak positions of the nanocomposites at low content of nanofiller shifted more to higher temperature compared to those of nanocomposites containing high concentrations of nanofiller. Dynamic rheometry, using a parallel plate rheometer, showed that the rheological moduli of the nanocomposites increased with increase in nanofiller concentration; however, this increase was greater in the high-frequency region. These results showed that increasing the concentration of nanofiller, and the consequent coalescence effect within the nanocomposites, led to rheological moduli values similar to those of the microcomposite. The TGA and LOI results of the microcomposite and nanocomposite containing 4wt.% of nanosilica showed that nanosilica had a more significant effect to enhance the heat and flame resistance of nylon 6,6 compared to that of micron-sized silica.
Acknowledgement
The authors gratefully acknowledge the Research Vice Chancellor of Islamic Azad University of Shahreza, Gachsaran and his coworkers for their help and assistance.