Characterization of Al2O3 Samples and NiAl-Al2O3 Composite Consolidated by Pulse Plasma Sintering.

Katarzyna Konopka,Konrad Cymerman,Paulina Piotrkiewicz,Justyna Zygmuntowicz,Marek Krasnowski,Marcin Wachowski

doi:10.3390/ma14123398

Katarzyna Konopka, Konrad Cymerman + Show 4 more

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https://doi.org/10.3390/ma14123398

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Abstract

The paper describes an investigation of Al2O3 samples and NiAl–Al2O3 composites consolidated by pulse plasma sintering (PPS). In the experiment, several methods were used to determine the properties and microstructure of the raw Al2O3 powder, NiAl–Al2O3 powder after mechanical alloying, and samples obtained via the PPS. The microstructural investigation of the alumina and composite properties involves scanning electron microscopy (SEM) analysis and X-ray diffraction (XRD). The relative densities were investigated with helium pycnometer and Archimedes method measurements. Microhardness analysis with fracture toughness (KIC) measures was applied to estimate the mechanical properties of the investigated materials. Using the PPS technique allows the production of bulk Al2O3 samples and intermetallic ceramic composites from the NiAl–Al2O3 system. To produce by PPS method the NiAl–Al2O3 bulk materials initially, the composite powder NiAl–Al2O3 was obtained by mechanical alloying. As initial powders, Ni, Al, and Al2O3 were used. After the PPS process, the final composite materials consist of two phases: Al2O3 located within the NiAl matrix. The intermetallic ceramic composites have relative densities: for composites with 10 wt.% Al2O3 97.9% and samples containing 20 wt.% Al2O3 close to 100%. The hardness of both composites is equal to 5.8 GPa. Moreover, after PPS consolidation, NiAl–Al2O3 composites were characterized by high plasticity. The presented results are promising for the subsequent study of consolidation composite NiAl–Al2O3 powder with various initial contributions of ceramics (Al2O3) and a mixture of intermetallic–ceramic composite powders with the addition of ceramics to fabricate composites with complex microstructures and properties. In composites with complex microstructures that belong to the new class of composites, in particular, the synergistic effect of various mechanisms of improving the fracture toughness will be operated.

Highlights

Ceramic matrix composites are an important group of composites developed over many years
Ceramic–metal composites belong to this group of materials
Metal particles located in the ceramic matrix interact with propagating cracks and cause deflection of the crack, bridging or stopping the cracks

Summary

Introduction

Ceramic matrix composites are an important group of composites developed over many years. Ceramic–metal composites belong to this group of materials. New methods of fabrication and new types of these materials have been elaborated on. It is not the only metal that is so active in improving the fracture behavior of brittle ceramic or intermetallic matrix composites. Intermetallic phases and other compounds are regarded as reinforcement of composites [13,14,15,16,17,18,19]. Particular attention has been paid to intermetallic matrix composite particle-reinforced intermetallic compounds or ceramics. In work [18], Al2 O3 particle reinforced TiAl composites were reaction-synthesized from a powder mixture of

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