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Abstract
In this study, pure Al and Mg were used to produce Al3Mg2 intermetallic compound. Then, Al3Mg2 alloy ingot was milled in an attrition ball mill to obtain fine Al3Mg2 powder. Al–10 wt. %Al3Mg2 nanocomposite was fabricated at different milling times (0–20 h). The effect of milling time on the properties of the obtained powders was studied. X-ray diffraction analysis was used to investigate phase composition and crystal size of the milled powders. Phase identification and the microstructure of the milled powders were investigated using field emission scanning electron microscopy as well as energy-dispersive spectrometer. The results revealed that the size of Al3Mg2 powders reduces significantly with milling time (<100 nm) with noticeable ultrafine grains of Al matrix. Uniform distribution of nano-sized Al3Mg2 particles in the aluminium matrix was also achieved with increasing milling time. Further, the results revealed that the crystallite size of nanocomposite powders decrease with increasing milling time, while saved lattice strain increases seriously. The mechanism of milling in the current system was specified as ductile–brittle type. It was concluded that the brittle particles of Al3Mg2 act as one of milling agent and so the presence of them could reduce the particle size of Al matrix, effectively.