Formation of Thick Immersion Coatings and Residual Stress Evaluation in the System ZrB2–ZrO2: Experimental and Numerical Investigation

The combination of various oxide ceramics in layered and functionally graded composites allows for the development of novel materials, including for high-temperature applications. This study demonstrates the possibility of obtaining a thick ZrO2-based coating on a ZrB2–SiC ceramic substrate by the i...

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Bibliographic Details
Published in:Materials 2023-01, Vol.16 (2), p.781
Main Authors: Buyakov, Ales, Smolin, Igor, Zimina, Valentina, Fedyanin, Nikita, Shmakov, Vasiliy, Buyakova, Svetlana
Format: Article
Language:English
Subjects:
Ceramics
Cold
Cold plasmas
Composite materials
Contact angle
Crack propagation
Density
Finite element method
Functionally gradient materials
Heat conductivity
High temperature
Impact strength
Indentation
Particle size
Phase composition
Plasma
Polyvinyl alcohol
Refractory materials
Residual stress
Silicon carbide
Silicon substrates
Sintering
Stress measurement
Submerging
Surface layers
Transition layers
Wettability
Zirconium compounds
Zirconium dioxide
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Summary:The combination of various oxide ceramics in layered and functionally graded composites allows for the development of novel materials, including for high-temperature applications. This study demonstrates the possibility of obtaining a thick ZrO2-based coating on a ZrB2–SiC ceramic substrate by the immersion method. For better wettability, the porous ZrB2–SiC substrate is treated with cold plasma without changing the structure and phase composition of the surface. Immersion of the substrate in a ZrO2-based slurry results in the formation of a gradient transition layer due to ZrO2 particle penetration into the pore volume. The interfacial residual microstresses are evaluated experimentally. The residual macrostresses in the samples are calculated by finite element simulation. It is shown that the thermal residual stresses in the ZrB2–SiC substrate are compressive and do not exceed 43 MPa. In the ZrO2 coating and transition layers of the composite, the residual stresses are tensile. Their values increase as they get closer to the outer layer of the ZrO2 coating and reach 1525 MPa. This confirms the conclusions about the presence of tensile residual stresses made in the experimental part of the work when observing crack propagation in the surface layers during indentation.
ISSN:1996-1944
1996-1944
DOI:10.3390/ma16020781