Abstract
The present work reports the effect of the extrusion nozzles' size and consequent residual porosity on the flexural strength of 3Y-TZP bioceramics fabricated by direct write assembly technology. A printable ink containing a volume fraction of 45% of 3Y-TZP (ZrO2 stabilized with 3mol% Y2O3) submicron powder, carboxymethyl cellulose and polyethyleneimine as additives was fine-tuned by rheological measurements. Different nozzle diameters (0.41mm, 0.33mm, and 0.25mm) were used to print 3D specimens with proper dimensions for structural and mechanical characterization after sintering, namely relative density, linear shrinkage, and three-point flexural strength. Bulk surface sample and exposed fractured surfaces after flexural strength tests were analyzed by X-ray diffraction, Rietveld refinement and scanning electronic microscopy. Strength reliability and failure probability of the three sample groups were analyzed by Weibull statistics. The sintered samples exhibited relative densities in the range of 78% (nozzle Ø 0.41=mm) and 82% (nozzle Ø 0.25=mm), i.e., a slight increase in the residual interfilamentous porosity is observed, as the extrusion tip diameter increases, while linear shrinkage is statistically similar (≈25%). Likewise, a progressive reduction of flexural strength and Weibull modulus as nozzle diameter increases was noticeable, being respectively σf=337,5±49MPa and m=6.6 for the smallest nozzle diameter (Ø=0.25mm) and σf=261.4±79MPa and m=3.2 for the biggest one (Ø=0.41mm). Unlike nozzle diameter, the material is constituted by 79-81wt% tetragonal t-ZrO2 and 19-21wt% cubic c-ZrO2 with equiaxed grain sizes between 0.3 and 0.6μm. X-ray diffraction analyses on the fracture surface of flexural test samples suggests that the toughening mechanism by tetragonal→ monoclinic phase transformation is the main responsible for the mechanical strength of this structural ceramic. Additionally, the reduction of flexural strength for samples printed with extrusion nozzle of 0.41mm could be explained by the surface roughness of the bending surfaces, as well as the lower effective resistance to crack-propagation arising from the higher size of residual pores on the fracture surface.
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