5. ConclusionsEG/CB and i-MG/CB fill

5. Conclusions
EG/CB and i-MG/CB filled rubber composites based on different synthetic rubbers were fabricated by melt blending. As a result of large surface area and the presence of polar groups on the surface of the nanofillers, the physical interaction and interfacial adhesion between the nanofillers and the rubber matrices were enhanced, which resulting in an improvement in the physical, mechanical and thermo-mechanical properties of the rubber nanocomposites. Becauseofthelargesurfaceareaof thenanofillers,thefilledrubber composites exhibit fast curing reaction, which resulting in a decrease in the scorch (TS2) and optimum cure time (Tc90). We have observed improved storage modulus, lower rolling resistance and better antiskid properties for the EG/CB and i-MG/CB loaded SBR/ BR blends compared to their respective controls. The different rubber composites show increase in the thermal stability compared to the controls. EG and i-MG filled BR, SBR and SBR/BR compounds exhibit an increase in the hardness, which resulting in an improvement in the abrasion resistance of the respective composite. Because of the higher basal spacing and exfoliated structure of i-MG sheets than EG flakes, i-MG sheets were uniformly dispersed inthedifferentrubbermatricesinthepresenceofCB,whichresulting in a superior mechanical, dynamic mechanical and thermal properties of the i-MG loaded rubber composites compared to the EG filled rubber vulcanizates.
Acknowledgement
Authors are deeply grateful to the Council of Scientific and Industrial Research (CSIR), New Delhi, India for their beneficent financial support.
References
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