Litcius/Paper detail

Low temperature densification mechanism and properties of Ta1-Hf C solid solutions with decarbonization and phase transition of Cr3C2

Buhao Zhang, Jie Yin, Yichen Wang, Duo Yu, Huan Liu, Xuejian Liu, Michael J. Reece, Qing Huang

2020Journal of Materiomics16 citationsDOIOpen Access PDF

Abstract

As a novel member of the ultra-high temperature ceramic family, which have extremely high melting points and remarkable hardness, Ta1-xHfxC solid solution ceramics are promising for applications in thermal protection systems. Ta1-xHfxC (x = 0, 0.2, 0.5, 0.8, and 1.0) with 2 vol% Cr3C2, were densified up to 98.8% at 2000 °C using a two-step spark plasma sintering process. Effect of Cr3C2 on the linear shrinkage of Ta1-xHfxC was investigated. Possible ‘eutectic’ reaction within TaCCr3C2 ceramic was inferred to contribute to the shrinkage at 1462 °C. High-angle annular dark-field scanning transmission electron microscopy combined with energy-dispersive spectroscopy was employed to further confirm the mutual diffusion between rock-salt structured ‘CrCx’ and TaC. Flexural strength, fracture toughness and Vicker’s hardness of Ta1-xHfxC ceramics were in the range of 439–492 MPa, 4.0–5.8 MPa∙m1/2 and 14.9–19.9 GPa respectively. The coefficient of thermal expansion (in the temperature range of 25–1000 °C) and thermal conductivity (at 1000 °C) of Ta1-xHfxC varied from 7.17 to 7.51 × 10−6 K−1 and 31.9–42.9 W/m·K, respectively. The high-temperature strength of Ta0.5Hf0.5C decreased to 165 MPa up to 1600 °C, approximately 34% of room-temperature strength, and a ‘zig-zag’ load-displacement curve was observed.

Topics & Concepts

Materials scienceEutectic systemCeramicSpark plasma sinteringFlexural strengthThermal expansionFracture toughnessComposite materialSinteringAtmospheric temperature rangeAnalytical Chemistry (journal)MicrostructureThermodynamicsChemistryChromatographyPhysicsAdvanced materials and compositesAdvanced ceramic materials synthesisMXene and MAX Phase Materials