Effect of the Cu/Mg Ratio on Mechanical Properties and Corrosion Resistance of Wrought Al-Cu-Mg-Ag Alloy

The present study aimed to investigate the influence of magnesium (Mg) on the mechanical properties and corrosion behavior of wrought Al-4Cu-xMg-0.6Ag alloys. The results from Optical Microscope, SEM, XRD analysis, and Thermo-Calc simulation were used to identify the microstructure formed after the aging process. Testing for hardness and tensile strength was conducted, in addition to corrosion testing. It was found that Mg significantly impacts the hardness of the alloys, with a high Mg content (low Cu/Mg ratio) increasing the hardness but reducing the tensile strength and ductility. This study attributed this to the formation of the S phase, which is dependent on both the quantity in the bulk and the size of the phase. The grain size was found to be finer with a higher Mg content, since the particle size inhibits grain growth during the artificial aging process. Counterintuitively, the corrosion activity was reduced in the high-Mg-content alloy due to its large particle size and the reduced galvanic cell effect. This study highlighted the importance of considering the effects of Mg on the mechanical properties and corrosion behavior of Al-Cu-Mg-Ag alloys.

Automated summary

The influence of magnesium (Mg) on the mechanical properties and corrosion behavior of Al-4Cu-xMg-0.6Ag alloys was investigated. The microstructure formed after the aging process was identified using Optical Microscope, SEM, XRD analysis, and Thermo-Calc simulation. Hardness and tensile strength testing, as well as corrosion testing, were conducted. It was found that Mg significantly impacts the hardness of the alloys, with a high Mg content increasing the hardness but reducing the tensile strength and ductility. The corrosion activity was reduced in the high-Mg-content alloy due to its larger particle size and reduced galvanic cell effect.