Strengthening die-cast Al-Mg and Al-Mg-Mn alloys with Fe as a beneficial element

The effect of Fe and Mn on the microstructure and mechanical properties of a series of Al-5 wt%Mg alloys processed by high pressure die casting (HPDC) was investigated. The Calculation of Phase Diagrams modelling (CALPHAD) was also carried out to understand the phase formation in experimental alloys. The results show that Fe can be a beneficial element in the Al-Mg and Al-Mg-Mn alloys to improve the mechanical properties. Fe only exists in the form of equilibrium Al13Fe4 phase in Al-Mg-Fe alloys. While, the addition of 0.6 wt%Mn suppresses the formation of equilibrium Al13Fe4 phase. In Al-Mg-Mn-Fe alloys, all Fe-rich intermetallics are Al-6(Fe, Mn) phase when Fe level is less than 2.5 wt%. When further increasing the Fe level, the primary non-equilibrium Al-6(Fe, Mn) phase gradually evolves to form equilibrium Al13Fe4 phase, but the eutectic phase is still Al-6(Fe, Mn). It was also found that both the eutectic Al13Fe4 in Al-Mg-Fe alloys and eutectic Al-6(Fe, Mn) in Al-Mg-Mn-Fe alloys are divorced from alpha-Al phases as the primary Fe-rich phases appear. The Fe-rich intermetallics significantly affect the mechanical properties of experimental alloys. Fe enhances the yield strength obviously but reduces the elongation significantly. The ultimate tensile strength is also improved by Fe addition when Fe level is less than 2.0 wt%, but it is significantly decreased with further increasing the Fe level. Moreover, the Mn addition is found to increase the volume of strengthening Fe-rich intermetallic and thus can further strengthen Al-Mg alloys.