A comparative study of nano-fillers to improve toughness and modulus of polymer-derived ceramics

Brittleness is a major limitation of polymer-derived ceramics (PDCs). Different concentrations of three nanofillers (carbon nanotubes, Si3N4 and Al2O3 nanoparticles) were evaluated to improve both toughness and modulus of a commercial polysilazane (PSZ) PDC. The PSZs were thermally crosslinked and pyrolyzed under isostatic pressure in nitrogen. A combination of mechanical, chemical, density, and microscopy characterizations was used to determine the effects of these fillers. Si3N4 and Al(2)O(3 )nanoparticles (that were found to be active fillers) were more effective than nanotubes and improved the elastic modulus, hardness, and fracture toughness (J(IC)) of the PDC by similar to 1.5 x, similar to 3 x, and similar to 2.5 x, respectively. Nanotubes were also effective in maintaining the integrity of the samples during pyrolysis. The modulus and hardness of PDCs correlated positively with their apparent density; this can provide a fast way to assess future PDCs. The improvement in fracture toughness was attributed to crack deflection and bridging observed in the micro-indentation cracks in the modified PDCs. The specific toughness of the modified PDCs was 4 x higher than that of high-purity alumina, and its specific modulus reached that of commercially available technical ceramics. These PDCs can also easily take different shapes and therefore are of interest in protective armor, propulsion, thermal protection, device packaging and biomaterial systems.

Automated summary

The addition of Si3N4 and Al2O3 nanoparticles can significantly improve the toughness and modulus of commercial polysilazane (PSZ) polymer-derived ceramics (PDCs). Additionally, carbon nanotubes are effective in maintaining sample integrity during pyrolysis. The density of PDCs is positively correlated with their modulus and hardness, providing a fast way to assess their performance.