Ultra high-pressure spark plasma sintered ZrC-Mo and ZrC-TiC composites

Ultra-high-pressure spark plasma sintering was applied to ZrC-20wt%Mo and ZrC-20wt%TiC composites with a pressure up to 7.8GPa and temperatures of 1550°C and 1950°C. Mechanical performance of the composites was benchmarked against a plain ZrC produced by the same method. Both composites outperformed...

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Bibliographic Details
Published in:International journal of refractory metals & hard materials 2016-12, Vol.61, p.201-206
Main Authors: Yung, Der-Liang, Cygan, Sławomir, Antonov, Maksim, Jaworska, Lucyna, Hussainova, Irina
Format: Article
Language:English
Subjects:
Carburizing
Composite materials
Degradation
Diffraction
Dissolution
Formations
Fracture toughness
HPHT
Indentation
Mechanical properties
Miscibility
Miscibility gap
Morphology
Oxidation
Plasma sintering
Solid state
Spark plasma sintering
Studies
Temperature
Titanium carbide
Titanium dioxide
Titanium oxides
X-ray diffraction
Zirconium dioxide
ZrC-Mo
ZrC-Ti
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Summary:Ultra-high-pressure spark plasma sintering was applied to ZrC-20wt%Mo and ZrC-20wt%TiC composites with a pressure up to 7.8GPa and temperatures of 1550°C and 1950°C. Mechanical performance of the composites was benchmarked against a plain ZrC produced by the same method. Both composites outperformed the pure ZrC with superior hardness and indentation fracture toughness of 2239HV1 and 5.4MPam1/2, and 1896HV1 and 5.9MPam1/2, respectively, for ZrC-Mo and ZrC-TiC composites. It was shown that ultra-high compaction pressure affected the ZrC-20 wt%TiC miscibility gap by lowering the temperature threshold from the usually applied 1800°C down to 1550°C resulting in formation of the solid state solution of (Zr,Ti)C. In contrast, the high pressure does not inhibit the carburisation of Mo with ZrC to form MoC, even when experiments were performed in a graphite free environment. The equiaxed morphology of ZrC grains along with a right-shift in XRD peaks for ZrC indicates dissolution of Mo in ZrC resulting in formation of the solid solution of (Zr,Mo)C. High-temperature X-ray diffraction analysis under oxidation conditions was performed on the samples showing degradation of ZrC-20wt%Mo due to the oxidation of Mo at high-temperature leading to MoO3 vaporisation. Conversely, the oxidation of ZrC-20wt%TiC composites was characterised by formation of ZrO2 and TiO2 remaining stable up to 1500°C. •Ultra-high pressure processing is for the first time applied to ZrC-based composites•High pressure does not significantly affect mechanical properties of the composites•HPHT SPS does not inhibit the eutectic reaction between Mo and ZrC•Sintering in non-carburising environment does not prevent reaction between ZrC and Mo•HPTH SPS lowers the miscibility gap temperature for ZrC-20wt%TiC
ISSN:0263-4368
2213-3917
DOI:10.1016/j.ijrmhm.2016.09.014