The grain refining
efficacy of titanium, aluminium and niobium borides, as well as niobium
aluminides, introduced via commercial and lab made master alloys on Al-Si
alloys was investigated. Significant grain refinement is achieved via the
introduction of these heterogeneous nuclei regardless of their nature,
stoichiometry of the master alloy, and addition rate. However, the grain
refinement is affected by variable such as contact time and cooling rate. In
the case of borides, the chemical inoculation efficiency is greatly affected by
their thermodynamic stability in molten Al-Si alloys. Conversely, the grain
refining potency of properitectic Al3Nb remains unaffected. The
underlying grain refining mechanism was finally investigated using current
model based on the growth restriction factor Q to simultaneously consider the effect of nucleants potency and alloy
chemistry. Among Ti-, Al- and Nb-based borides with similar particle size and
distribution, the latter are the most efficient to grain refine Al-Si alloys.