Structure, Strength, and Oxidation Resistance of Ultrahigh-Temperature ZrB2–SiC–WC Ceramics

The hot pressing process was employed to produce dense ultrahigh-temperature ZrB 2 –15 vol.% SiC–5 vol.% WC ceramics. Refractory (Zr, W)C and WB phases emerged in hot pressing at 2050°C and 30 MPa with a holding time of 15 min. The hot pressing process was peculiar in that a (Zr, W)B 2 solid solutio...

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Published in:Powder metallurgy and metal ceramics 2021-05, Vol.60 (1-2), p.60-68
Main Authors: Vedel, D.V., Grigoriev, O.N., Mazur, P.V., Osipov, A.E.
Format: Article
Language:English
Subjects:
Boron
Boron oxides
Borosilicate glass
Ceramics
Characterization and Evaluation of Materials
Chemistry and Materials Science
Composites
Depletion
Glass
Grain boundaries
High temperature
Hot pressing
Materials Science
Metallic Materials
Natural Materials
Oxidation
Oxidation resistance
Refractory and Ceramic Materials
Refractory materials
Room temperature
Scale (corrosion)
Silicon carbide
Silicon dioxide
Solid solutions
Tungsten carbide
Zirconium
Zirconium compounds
Zirconium dioxide
Zirconium oxides
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Summary:The hot pressing process was employed to produce dense ultrahigh-temperature ZrB 2 –15 vol.% SiC–5 vol.% WC ceramics. Refractory (Zr, W)C and WB phases emerged in hot pressing at 2050°C and 30 MPa with a holding time of 15 min. The hot pressing process was peculiar in that a (Zr, W)B 2 solid solution formed at the zirconium boride grain boundaries. Annealing in vacuum at 1600°C decreased the amount of oxygen in the ceramics from 0.3 to 0.1 wt.% through interaction of B 2 O 3 , SiO 2 , and ZrO 2 with tungsten carbide. The ZrB 2 –15 vol.% SiC–5 vol.% WC ceramics had 505 ± 60 MPa strength at room temperature and 802 ± 94 MPa strength at 1800°C. The high strength at 1800°C was reached through transcrystalline fracture of zirconium boride grains. High-temperature oxidation resulted in scale consisting of three layers: borosilicate glass as the upper layer, zirconium oxide with other oxide phases (WO 3 and SiO 2 ) as the middle layer, and the base material depleted of boron and silicon as the lower layer. At an oxidation temperature of 1500°C and a holding time of 50 h, the scale was 85 μm thick, including a SiO 2 –B 2 O 3 layer 64 μm thick and a layer of ZrO 2 + SiO 2 + Me x O y and base material depleted of boron and silicon. At an oxidation temperature of 1600°C and a holding time of 2 h, the scale was 84 μm thick, including a SiO 2 –B 2 O 3 layer 10 μm thick and a layer of ZrO 2 + SiO 2 + Me x O y and base material depleted of boron and silicon. The dense scale developed on the material allowed 70% of its initial strength to be retained after oxidation at 1500°C with a holding time of 50 h and 50% strength after oxidation at 1600°C for 2 h, which was higher than for the base ZrB 2 –15 vol.% SiC–5 vol.% ceramics.
ISSN:1068-1302
1573-9066
DOI:10.1007/s11106-021-00215-3