Microstructural Investigation and High Temperature Mechanical Behavior of AXE622 Cast Mg Alloy

The microstructure and high temperature properties of the AXE622 Mg alloy were investigated after the conventional and semisolid casting processes. The tensile test was conducted at room temperature, and 473 K. Impression creep test was performed at a temperature range of 423-498 K under the stress range of 450-600 MPa. The microstructure of the conventional and semisolid alloys contains alpha-Mg dendrites, the eutectic phase, secondary phases including (Mg-Al)(2)Ca, eutectic Mg17Al12, and Al11RE3. During semisolid processing, coarse dendrites of the alpha-Mg became fine, globular, and Rosetta shape. The average length of the secondary phases in the semisolid alloy decreased from 4.21 to 2 mu m and the average grain size of the alpha-Mg reduced from 113 to 96 mu m. Semisolid processing caused a significant improvement in the tensile and creep resistance of the AXE622 Mg alloy. The stress exponent for creep was calculated in the range 5.6-7.7 for the conventional alloy and in the range 10.3-11 for the semisolid alloy. The activation energy for conventional and semisolid alloy was determined as 71.4 kJ/mol and 78.3 kJ/mol, respectively. It was concluded that the dominant creep mechanism in the conventional alloy was the grain boundary diffusion-controlled dislocation climb, while in the semisolid alloy was the power-law breakdown.

Automated summary

The microstructure and high temperature properties of AXE622 magnesium alloy were investigated after conventional and semisolid casting processes. Semisolid processing significantly improved the tensile and creep resistance of the alloy. The dominant creep mechanism in the conventional alloy was grain boundary diffusion-controlled dislocation climb, while in the semisolid alloy it was power-law breakdown.