Significant Microstructure Refinement and Improved Mechanical Properties of Mg2Si/Al Composites Induced by Nanoscale TiB2 Particles

Aluminum matrix composite have shown the great prospects in improving service performance and life of high-end equipment under harsh conditions due to lightweight and high specific strength. However, the presence of coarse Mg₂Si phase with undesired morphology in Mg₂Si/Al composites limits their engineering application. This study proposes a strategy of TiB₂ ceramic particles regulating the morphology and size of Mg₂Si to strengthen the aluminum matrix composites by incorporating dual-scale hybrid reinforcements of Mg₂Si and TiB₂. The TiB₂ particles were introduced into the Al-15 wt pct Mg₂Si composite by a master alloy method, and the influence of TiB₂ particles on the morphology and size of Mg₂Si, and Al grains of composites were investigated. The results demonstrate that 3 wt pct TiB₂ particles can refine the primary Mg₂Si from 14.6 to 10.4 μm, resulting in a more regular morphology. Additionally, the eutectic Mg₂Si transforms from a long and slender Chinese character shape to a short rod shape, reducing the aspect ratio by 65.9 pct from 10.9 to 3.7. During the solidification process, TiB₂ particles promote the heterogeneous nucleation of primary Mg₂Si phases and impede the growth, leading to significant refinement. However, the improved morphology of eutectic Mg₂Si is mainly attributed to the inhibited preferential growth due to the formation of a nanoparticle layer, with no observed heterogeneous nucleation of TiB₂. Moreover, TiB₂ particles significantly refine the grain size of Al from 212.7 to 70.8 μm. The addition of 3 wt pct TiB₂ greatly improves the strength of the composites from 302 to 373 MPa, without losing ductility. After T6 heat treatment, Al-15 wt pct Mg₂Si composites exhibit simultaneous improvement in the strength and ductility. Compared with composites without TiB₂ particles (361 MPa and 32 pct), Al-15Mg₂Si-3TiB₂ composites have more superior strength–ductility combination of 434 MPa and 35 pct due to the significant modification of Mg₂Si phase, grain refinement, and Orowan strengthening.

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