Additive manufacturing of fine-grained high-strength titanium alloy via multi-eutectoid elements alloying

Developing fine-grained high-strength titanium (Ti) alloys by additive manufacturing has boomed interest for both research and application. The eutectoid element addition has been demonstrated as a feasible approach; however, solid solubility of the eutectoid elements in Ti alloys is limited, and the excessive eutectoid element addition could form brittle intermetallics and thereby deteriorating the ductility. To address this challenge, here we demonstrate a novel multi-eutectoid elements alloying approach based on thermodynamic prediction to achieve refined microstructure and high strength in Ti alloys. The trace eutectoid alloy elements Co, Cr, and Ni were in-situ alloyed with the Ti-6Al-4V alloy synergistically through laser-directed energy deposition. Moreover, a heterostructured titanium alloy was also fabricated by manipulating the spatial distribution of the eutectoid elements. Interestingly, the multiple eutectoid elements contribute to the in-situ decomposition of alpha ', thereby bringing a favourable ultrafine alpha//9 microstructure. Tensile strength of-1.34 GPa and ductility of-5.1% are attained with eutectoid elements addition, suggesting a superior combination of strength and ductility. The mechanisms regarding grain refinement, variant selection, strengthening, and toughening were investigated intensively. This work could provide significant guidance for microstructure engineering and performance enhancement in additively manufactured Ti alloys.

Automated summary

A novel multi-eutectoid elements alloying approach based on thermodynamic prediction is demonstrated to achieve refined microstructure and high strength in Ti alloys. Trace eutectoid alloy elements Co, Cr, and Ni were in-situ alloyed with the Ti-6Al-4V alloy through laser-directed energy deposition, resulting in superior combination of strength and ductility.