Reactive consolidation and high-temperature strength of HfB2-SiB6

During the spark plasma sintering at 1900 ?, SiB6 decomposes into cubic silicon carbide and boron carbide, owing to the reducing environment of the furnace. For the HfB2-SiB6 ceramic improvement in hardness (24.5 +/- 0.7 GPa) was attributed to the formation of the B12(C,Si,B)3. Fracture toughness by indentation (6.8 +/- 2.4 MPa.m1/2), single-edge notched bend specimens (4.6 +/- 0.4 MPa.m(1/2)) and room-temperature strength (513 & PLUSMN; 21 MPa) of the HfB2-SiB6 composite produced by spark plasma sintering was higher or on the same level as the HfB2-SiC ceramics. The high-temperature flexural strength tests suggested that the strength would decrease monotonically with an increase in temperature. At or below 1600 C, only a linear stress-strain response was observed, and resulted into a mean strength of-320 MPa. During the tests at 1800 ?, we observed a nonlinear deformation indicating ongoing plastic deformation which led to a strength decrease down to 230 & PLUSMN; 30 MPa.

Automated summary

During spark plasma sintering, SiB6 decomposes into cubic silicon carbide and boron carbide. The HfB2-SiB6 composite material has better hardness, toughness, and strength compared to HfB2-SiC ceramics. The strength decreases with increasing temperature under high-temperature conditions.