Microstructure and mechanical properties of cast Al-Ce-Sc-Zr-(Er) alloys strengthened by Al₁₁Ce₃ micro-platelets and L1₂ Al₃(Sc,Zr,Er) nano-precipitates

The microstructure and mechanical properties of two die-cast hypoeutectic Al-Ce-based alloys modified with Sc, Zr and Er micro-additions – Al-1.5Ce-0.14Sc-0.03Zr with high Sc content and Al-1.4Ce-0.02Sc-0.06Zr-0.003Er (at%) with low Sc content – are studied, with focus on the two strengthening phases: micron-scale Al₁₁Ce₃ platelets formed on solidification and L1₂ Al₃(Sc,Zr,Er) nanoprecipitates formed during aging. The evolution of microstructure and microhardness upon isothermal aging at 350 and 400 °C, and the creep resistance at 300 °C, are studied and compared to alloys containing only one of these strengthening phases. The Al₁₁Ce₃ and L1₂ phases form mostly independently of each other, except in the low-Sc alloy where scavenging of Er and Si by Al₁₁Ce₃ on solidification reduces the kinetics of precipitation and number density of the L1₂ precipitates formed on subsequent aging. The two strengthening phases, while mostly independent of each other chemically, interact synergistically in terms of strengthening. At ambient temperature, the hardness of the Al₁₁Ce₃- and L1₂-strengthened alloys is higher than that of similar alloys containing only one strengthening phase. At 300 °C, the creep strain rate is reduced by as much as five orders of magnitude in the Al₁₁Ce₃- and L1₂-strengthened alloys compared to alloys containing only L1₂ precipitates. This improvement in both room and elevated-temperature mechanical properties is modeled through a combination of load transfer from the Al₁₁Ce₃ micro-platelets, and precipitation strengthening from the Al₃(Sc,Zr,Er) nanoprecipitates.