A facile high-efficiency preparation strategy for Al-containing multi-component boride microcrystals with superior comprehensive performance.

• A novel Al-Containing multi-component boride (MMB 2) was efficiently prepared. • The corresponding in-situ reaction process and growth mechanism are proposed. • The Al-Containing MMB 2 exhibits ultra-high hardness and improved toughness. • The Al-Containing MMB 2 shows superior oxidation activation energy. Multi-component transition group metal borides (MMB 2) have become a research hotspot due to their new composition design concepts and superior properties compared with conventional ceramics. Most of the current methods, however, are complicated and time-consuming, the mass production remains a challenge. Herein, we proposed a new high-efficiency strategy for synthesis of MMB 2 using molten aluminum as the medium for the first time. The prepared Al-containing multi-component borides (TiZrHfNbTa)B 2 microcrystals had a homogeneous composition with a hexagonal AlB 2 structure and ultra-high hardness value of ∼35.3 GPa, which was much higher than data reported in the literature and the rule of mixture estimations. Furthermore, combined with the First-principles calculation results, we found that the Poisson's ratio (v) values exhibit a clearly ascending trend from 0.17 at VEC = 3.5 to 0.18 at VEC = 3.4, then to 0.201 at VEC = 3.2 with the increasing of Al content. This indicates that the intrinsic toughness of multi-component boride microcrystals is obviously enhanced by the trace-doped Al elements. Besides, the fabricated Al-containing multi-component boride microcrystals have superior oxidation activation energy and structural stability. The enhanced oxidation resistance is mainly attributed to the formation of a protective Al 2 O 3 oxide layer and the lattice distortion, both of which lead to sluggish diffusion of O 2. These findings propose a new unexplored avenue for the fabrication of MMB 2 materials with superior comprehensive performance including ultra-hardness and intrinsically improved thermo-mechanical properties. [Display omitted] [ABSTRACT FROM AUTHOR]