24-10-2012, 11:09 AM
Performance of Nanotube-Based Ceramic Composites: Modeling and Experiment
ABSTRACT
The excellent mechanical properties of carbon-nanotubes are driving research into the creation of new strong, tough
nanocomposite systems. In this program, our initial work presented the first evidence of toughening mechanisms operating in
carbon-nanotube- reinforced ceramic composites using a highly-ordered array of parallel multiwall carbon-nanotubes (CNTs)
in an alumina matrix. Nanoindentation introduced controlled cracks and the damage was examined by SEM. These
nanocomposites exhibit the three hallmarks of toughening in micron-scale fiber composites: crack deflection at the
CNT/matrix interface; crack bridging by CNTs; and CNT pullout on the fracture surfaces. Furthermore, for certain geometries
a new mechanism of nanotube collapse in shear bands was found, suggesting that these materials can have multiaxial damage
tolerance. The quantitative indentation data and computational models were used to determine the multiwall CNT axial
Young’s modulus as 200-570 GPa, depending on the nanotube geometry and quality.