Densification of ultra-refractory transition metal diboride ceramics

The densification behavior of transition metal diboride compounds was reviewed with emphasis on ZrB2 and HfB2. These compounds are considered ultra-high temperature ceramics because they have melting temperatures above 3000?C. Densification of transition metal diborides is difficult due to their str...

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Bibliographic Details
Published in:Science of sintering 2020, Vol.52 (1), p.1-14
Main Authors: Fahrenholtz, W.G., Hilmas, G.E., Li, Ruixing
Format: Article
Language:English
Subjects:
Bonding strength
Ceramics
Densification
Extreme values
Grain boundaries
Hafnium compounds
High temperature
Hot pressing
Impurities
Metals
Particle size
Plasma sintering
Refractory materials
Self diffusion
sintering
Spark plasma sintering
Studies
transition metal diborides
Transition metals
Ultrahigh temperature
Zirconium compounds
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Summary:The densification behavior of transition metal diboride compounds was reviewed with emphasis on ZrB2 and HfB2. These compounds are considered ultra-high temperature ceramics because they have melting temperatures above 3000?C. Densification of transition metal diborides is difficult due to their strong covalent bonding, which results in extremely high melting temperatures and low self-diffusion coefficients. In addition, oxide impurities present on the surface of powder particles promotes coarsening, which further inhibits densification. Studies prior to the 1990s predominantly used hot pressing for densification. Those reports revealed densification mechanisms and identified that oxygen impurity contents below about 0.5 wt% were required for effective densification. Subsequent studies have employed advanced sintering methods such as spark plasma sintering and reactive hot pressing to produce materials with nearly full density and higher metallic purity. Further studies are needed to identify fundamental densification mechanisms and further improve the elevated temperature properties of transition metal diborides. nema
ISSN:0350-820X
1820-7413
DOI:10.2298/SOS2001001F