Evaluating Microstructure and High-Temperature Shear Behavior of Hot Extruded Al-Al₁₃Fe₄ Nanocomposite

抄録

The microstructure and mechanical properties of extruded aluminum matrix composites reinforced with novel Al₁₃Fe₄ complex metallic alloy (CMA) nano-particles were investigated. The large grained structure of the hot pressed matrix was refined after addition of Al₁₃Fe₄ CMAs, the effect being more pronounced for Al-5 mass% Al₁₃Fe₄ composite. The hot pressed specimens were subjected to uniaxial hot extrusion process (with a 9 : 1 ratio at 400°C). This had a great effect on the microstructural evolution of the composites. High-temperature shear punch test (SPT) was employed to investigate the effects of 1–10 mass% Al₁₃Fe₄ additions on the microstructure and mechanical properties of the as-extruded Al/Al₁₃Fe₄ composite. The shear behavior of the alloys was investigated in the temperature range of 25–350°C. Al-5 mass% Al₁₃Fe₄ nanocomposite had the highest shear strength among all the materials tested at high temperature (150, 250 and 350°C), mainly due to the semi-ideal dispersion of the thermally stable Al₁₃Fe₄ nano-particles, and the refined microstructure of the extruded specimen, which results in pronounced enhancement in mechanical properties. These thermally resistant particles are believed to increase the resistance of the composite against the applied shear stress in the deformation zone during the subjection of the material to SPT.