Abstract
TiB2-TiC composite ceramics with tunable compositions (70 wt% < TiB2 < 100 wt%) were fabricated by the reactive spark plasma sintering (SPS) technique using Ti, B4C, and TiB2 as raw materials. The effects of sintering temperature and holding time on the densification, electrical, and mechanical properties of composite ceramics were investigated. Additionally, the competitive reaction behavior of the Ti-B4C-TiB2 ternary system and the formation mechanism of TiB2-TiC composite ceramics were systematically highlighted, respectively. The TiB2-TiC composite ceramics successfully obtained 98.9 % relative density, 8.0 ± 0.3 μΩ∙cm electrical resistivity, and 6.8 ± 0.2 MPa∙m1/2 fracture toughness at the sintering temperature of 1800 °C, pressure of 35 MPa, and holding time of 5 min. As the sintering temperature was increased in the Ti-B4C-TiB2 ternary system, competitive reactions occurred not only between Ti and B4C as well as between Ti and TiB2 reactants, but also between B4C and in-situ generated TiC, accompanied by the formation of TiB and free carbon in the system. The enhancement of fracture toughness could be attributed to the generation of TiB. Meanwhile, the establishment of a conductive network, which was promoted by the presence of free carbon, resulting in significant reduction in electrical resistivity. However, as a consequence of the deformation and dissociation of the free carbon, a reduction in the load-bearing cross-section resulted in a corresponding reduction in the flexural strength of the composite ceramic.
Published Version
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