TiN-Nanoparticulate-Reinforced ZrO2 for Electrical Discharge Machining

This study presents a fabrication route for an electrically conductive ZrO2–TiN ceramic nanocomposite with a nanoscale TiN phase occupying ≤30 vol% to improve the mechanical reinforcement of the zirconia matrix, and at the same time provide electrical conductivity to facilitate electro-discharge mac...

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Bibliographic Details
Published in:Materials 2019-08, Vol.12 (17), p.2789
Main Authors: Lazar, Ana, Kosmač, Tomaž, Zavašnik, Janez, Abram, Anže, Kocjan, Andraž
Format: Article
Language:English
Subjects:
Aqueous solutions
Ceramics
Composite materials
Crack bridging
Crystal structure
Diamond pyramid hardness tests
Electric discharge machining
Electrical resistivity
Evolution
Fracture toughness
Grain boundaries
Grain growth
Graphene
Ion beams
Mechanical properties
Microstructure
Nanocomposites
Nanoparticles
Phase composition
Plasma sintering
Sintering (powder metallurgy)
Spark plasma sintering
Synthesis
Tetragonal zirconia
Tetragonal zirconia polycrystals
Transmission electron microscopy
Yttria-stabilized zirconia
Yttrium oxide
Zirconium dioxide
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Summary:This study presents a fabrication route for an electrically conductive ZrO2–TiN ceramic nanocomposite with a nanoscale TiN phase occupying ≤30 vol% to improve the mechanical reinforcement of the zirconia matrix, and at the same time provide electrical conductivity to facilitate electro-discharge machining (EDM). The TiN nanoparticles were incorporated into a 3 mol% yttria-stabilized tetragonal zirconia (Y-TZP) powder, either by admixing a TiN nanopowder (MCP) or by using in-situ synthesis (ISS) via the forced hydrolysis of a titanyl sulphate aqueous solution and the direct nitriding of as-synthesized titania nanoparticles, followed by consolidation and rapid sintering in a spark plasma sintering (SPS) system. The initial phase composition and crystal structure of the as-synthesized powders and the sintered samples were characterized by transmission electron microscopy (TEM) and X-ray difraction (XRD). The influence of the different fabrication routes on the microstructural evolution, electrical and mechanical properties, and affinity for EDM were assessed using TEM, focused ion beam scanning electron microscopy (FIB-SEM, Vickers indentation, electrical conductivity measurements, and profilometry. The MCP synthesis route resulted in finer microstructures that are less prone to microstructural inhomogeneities; however, using the ISS route, it was possible to fabricate electrically conductive Y-TZP nanocomposites containing only 15 vol% of the TiN nanoparticulate phase. Both synthesis routes resulted in an increase of the fracture toughness with an increase of the TiN phase due to the nanoparticulate TiN reinforcement of the Y-TZP ceramic matrix via crack-bridging toughening mechanisms. As both synthesis routes yielded Y-TZP nanocomposites capable of successful EDM machining at a TiN content of ≥30 vol% for the MCP and ≥ 15 vol% TiN for the ISS, a possible mechanism was developed based on the microstructure evolution and grain growth.
ISSN:1996-1944
1996-1944
DOI:10.3390/ma12172789