Abstract:The microstructure and mechanical properties of friction stir processed Al-Mg₂Si alloys were studied by TEM and EBSD. The results showed that an increase in the tool rotation speed (300-700 r/min) led to a decrease in the defect area (from 10.5 mm² to zero), whereas the defect area demonstrated the opposite trend (increased to 1.5 mm² from zero) upon further increasing the rotation speed (700-1200 r/min). The types of defects were transformed from tunnel defects to fusion defects as the rotational speed increased. The coarse Mg₂Si dendrites were broken and fine particles (smaller than 10 mm) formed in the weld nugget (WN). The amount of low-angle grain boundaries increased significantly from 57.7% to 83.6%, which was caused by an increase in the content of the deformed structure (from 1.7% to 13.6%). The hardness, ultimate tensile strength (UTS) and elongation were all greatly improved for the weld nugget. The hardness values of the WNs had the following order: R300<R1200<R500<R900<R700. The UTS and elongation had the following order: BM (base material)<R300<R1200<R500<R900<R700. The UTS and the elongation for the WN were increased by one and three times, respectively.

Key words: Al-Mg₂Si alloy; friction stir processing; ultimate tensile strength; microstructural evolution; defect