Background:
The development of new bioimplants with enhanced mechanical and biomedical
properties have great impetus for researchers in the field of biomaterials. Metallic materials
such as stainless steel 316L (SS316L), applied for bioimplants are compatible to the human osteoblast
cells and bear good toughness. However, they suffer by corrosion and their elastic moduli
are very high than the application where they need to be used. On the other hand, ceramics such as
hydroxyapatite (HAP), is biocompatible as well as bioactive material and helps in bone grafting during
the course of bone recovery, it has the inherent brittle nature and low fracture toughness. Therefore,
to overcome these issues, a hybrid combination of HAP, SS316L and carbon nanotubes (CNTs)
has been synthesized and characterized in the present investigation.
Methods:
CNTs were acid treated to functionalize their surface and cleaned prior their addition to the
composites. The mixing of nano-hydroxyapatite (HAPn), SS316L and CNTs was carried out by nitrogen
gas purging followed by the ball milling to insure the homogeneous mixing of the powders. In
three compositions, monolithic HAPn, nanocomposites of CNTs reinforced HAPn, and hybrid nanocomposites
of CNTs and SS316L reinforced HAPn has been fabricated by spark plasma sintering
(SPS) technique.
Results:
SEM analysis of SPS samples showed enhanced sintering of HAP-CNT nanocomposites,
which also showed significant sintering behavior when combined with SS316L. Good densification
was achieved in the nanocomposites. No phase change was observed for HAP at relatively higher
sintering temperatures (1100°C) of SPS and tricalcium phosphate phase was not detected by XRD
analysis. This represents the characteristic advantage with enhanced sintering behavior by SPS technique.
Fracture toughness was found to increase with the addition of CNTs and SS316L in HAPn,
while hardness initially enhanced with the addition of nonreinforcement (CNTs) in HAPn and then
decrease for HAPn-CNT-SS316L hybrid nanocomposites due to presence of SS316L.
Conclusion:
A homogeneous distribution of CNTs and SPS technique resulted in the improved
mechanical properties for HAPn-CNT-SS316L hybrid nanocomposites than other composites and
suggested their application as bioimplant materials.
Fabrication of Cu-Based SiC Composites by Spark Plasma Sintering of Cu-Nitrate Coated SiC Powders
