Improvement of Mechanical Properties of Plasma Sprayed Al2O3–ZrO2–SiO2 Amorphous Coatings by Surface Crystallization

Ceramic Al2O3−ZrO2−SiO2 coatings with near eutectic composition were plasma sprayed using hybrid water stabilized plasma torch (WSP-H). The as-sprayed coatings possessed fully amorphous microstructure which can be transformed to nanocrystalline by further heat treatment. The amorphous/crystalline co...

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Bibliographic Details
Published in:Materials 2019-10, Vol.12 (19), p.3232
Main Authors: Medricky, Jan, Lukac, Frantisek, Csaki, Stefan, Houdkova, Sarka, Barbosa, Maria, Tesar, Tomas, Cizek, Jan, Musalek, Radek, Kovarik, Ondrej, Chraska, Tomas
Format: Article
Language:English
Subjects:
Aluminum oxide
Ceramic coatings
Ceramic glazes
Cooling
Crystallites
Crystallization
Eutectic composition
Grain size
Heat treating
Heat treatment
Laser beam heating
Lasers
Mechanical analysis
Mechanical properties
Microhardness
Microstructure
Nanocrystals
Phase composition
Plasma
Plasma jets
Plasma spraying
Protective coatings
Raw materials
Silicon dioxide
Sprayed coatings
Substrates
Wear resistance
Zirconium dioxide
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Summary:Ceramic Al2O3−ZrO2−SiO2 coatings with near eutectic composition were plasma sprayed using hybrid water stabilized plasma torch (WSP-H). The as-sprayed coatings possessed fully amorphous microstructure which can be transformed to nanocrystalline by further heat treatment. The amorphous/crystalline content ratio and the crystallite sizes can be controlled by a specific choice of heat treatment conditions, subsequently leading to significant changes in the microstructure and mechanical properties of the coatings, such as hardness or wear resistance. In this study, two advanced methods of surface heat treatment were realized by plasma jet or by high energy laser heating. As opposed to the traditional furnace treatments, inducing homogeneous changes throughout the material, both approaches lead to a formation of gradient microstructure within the coatings; from dominantly amorphous at the substrate–coating interface vicinity to fully nanocrystalline near its surface. The processes can also be applied for large-scale applications and do not induce detrimental changes to the underlying substrate materials. The respective mechanical response was evaluated by measuring coating hardness profile and wear resistance. For some of the heat treatment conditions, an increase in the coating microhardness by factor up to 1.8 was observed, as well as improvement of wear resistance behaviour up to 6.5 times. The phase composition changes were analysed by X-ray diffraction and the microstructure was investigated by scanning electron microscopy.
ISSN:1996-1944
1996-1944
DOI:10.3390/ma12193232