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Sintering Conditions, Microstructure and Properties of Alumina 10 vol% Zirconia Nanocomposites
F. Kern
Institut für Fertigungstechnologie keramischer Bauteile, Universität Stuttgart, (Institute for Manufacturing Technologies of Ceramic Components and Composites, University of Stuttgart), 70569 Stuttgart, Allmandring 7b, Germany
received September 21, 2011, received in revised form October 5, 2011, accepted October 12, 2011
Vol. 3, No. 1, Pages 1-8 DOI: 10.4416/JCST2011-00036
Abstract
Zirconia-toughened alumina (ZTA) ceramics of various compositions have high relevance in the field of mechanical engineering for cutting tools and wear parts as well as in biomedical applications for hip and knee implants.
In this study a matrix of submicron size α-alumina is reinforced with 10 vol% unstabilized zirconia nanoparticles. The ZTA ceramics were consolidated by means of hot pressing at 1400 – 1550 °C at 60 MPa axial pressure for 1 h in order to test the influence of the sintering conditions on the mechanical properties, microstructure and phase composition. Despite the conventional mixing and milling method used, ZTA nanocomposites of high homogeneity were obtained. Low sintering temperatures result in ultra-fine-grained materials with high hardness. High strength of 900 – 1050 MPa was observed over the whole sintering temperature range, while toughness rises with sintering temperature. A clear correlation between transformability of the tetragonal phase and toughness cannot be identified. Highest strength was found for ZTA with a low initial monoclinic content and high transformability. Increasing sintering temperatures led to only slight microstructural coarsening but to a migration of zirconia particles and rising monoclinic content. Associated with these effects, a gradual shift from transformation toughening to microcrack toughening was observed.
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Keywords
ZTA, nanocomposite, microstructure, phase composition
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