Abstract
Metal – ceramic composites have been fabricated by reactive infiltration with a laboratory squeeze caster. Two types of these composites are characterised by nanoindentation. While the first one contains Al2O3, TiO2 and Al, the second one contains Al2O3, TiAl3 as the main products and a little Ti5Si3. The phases of the second specimen are formed during infiltration. Hardness and Young’s modulus values in both composites were compared with measurements of the bulk material of each phase. A significant depth dependence of the properties was detected in the composite materials and simulated by a finite element analysis. The measured values agreed well with the simulation.
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© 2003 Carl Hanser Verlag, München
Articles in the same Issue
- Frontmatter
- Editorial
- Editorial
- Articles/Aufsätze
- On the origins and mechanisms of the indentation size effect
- Nanoindentation testing of gear steels
- Nanoscale materials testing under industrially relevant conditions: high-temperature nanoindentation testing
- Investigation of the properties of candidate reference materials suited for the calibration of nanoindentation instruments
- Approaches of quantifying the entire load–depth curve in terms of hardness
- Effect of interphase boundaries on nanoindentation experiments on a Ni-base alloy
- Nanoindentation measurements on infiltrated alumina–aluminide alloys
- The phase diagram of the Cd–In–Sn system
- Experimental study of the liquid/liquid interfacial tension in immiscible Al–Bi system
- Solid state synthesis of Al-based amorphous and nanocrystalline Al–Nb–Si and Al–Zr–Si alloys
- X-ray diffraction study on the microstructure of an Al–Mg–Sc–Zr alloy deformed by high-pressure torsion
- A laser-remelted complex manganese bronze with shape memory
- Notifications/Mitteilungen
- Personal/Personelles
- Books/Bücher
- Conferences/Konferenzen
Articles in the same Issue
- Frontmatter
- Editorial
- Editorial
- Articles/Aufsätze
- On the origins and mechanisms of the indentation size effect
- Nanoindentation testing of gear steels
- Nanoscale materials testing under industrially relevant conditions: high-temperature nanoindentation testing
- Investigation of the properties of candidate reference materials suited for the calibration of nanoindentation instruments
- Approaches of quantifying the entire load–depth curve in terms of hardness
- Effect of interphase boundaries on nanoindentation experiments on a Ni-base alloy
- Nanoindentation measurements on infiltrated alumina–aluminide alloys
- The phase diagram of the Cd–In–Sn system
- Experimental study of the liquid/liquid interfacial tension in immiscible Al–Bi system
- Solid state synthesis of Al-based amorphous and nanocrystalline Al–Nb–Si and Al–Zr–Si alloys
- X-ray diffraction study on the microstructure of an Al–Mg–Sc–Zr alloy deformed by high-pressure torsion
- A laser-remelted complex manganese bronze with shape memory
- Notifications/Mitteilungen
- Personal/Personelles
- Books/Bücher
- Conferences/Konferenzen