Effects of metalloid Si on the microstructure and mechanical properties of Fe36Ni36Cr10Mo1Al17-XSiX alloys

Multi-component alloys with good mechanical properties and casting liquidity have become a hotspot in the materials field. Typically, the addition of minor metal elements plays a vital role in strengthening the mechanical properties. However, doping metalloid elements such as Si into multi-component alloys is also an effective method to enhance the mechanical properties. In the present study, the effect of Si (0 similar to 4 at%) on the microstructure and mechanical properties was investigated within both as-cast and thermal mechanical treatment states. In as-cast state, all 4 alloys exhibited dendrites and interdendrites structure. The fine structure enhanced tensile strength for Si1 and improved ductility for Si2. Once the Si content reached 4 at%, both the strength and ductility dropped dramatically. Phase selective recrystallization and aging greatly increased the tensile strength and ductility simultaneously. The alloys with addition of Si had similar mechanical properties after thermal mechanical treatment process. Si2 after recrystallization and aging was considered a promising candidate for further application with a yield strength of 960 MPa, tensile strength of 1463 MPa and fracture strain of 20.5%. This work provided a new prospect to design multi-component alloys with nonmetallic elements, which may be applied to wear, corrosion and oxidation resistance fields.

Automated summary

The addition of minor metal and metalloid elements in multi-component alloys can improve their mechanical properties. In this study, the effect of silicon content on the microstructure and mechanical properties of multi-component alloys was investigated. The results showed that the alloys with silicon addition exhibited improved strength and ductility after thermal mechanical treatment, making them promising candidates for applications in wear, corrosion, and oxidation resistance fields.