High strength, low modulus, and ductile metastable beta Ti-Nb-Zr-Fe alloys by laser powder bed fusion in-situ alloying

doi:10.1016/j.jmst.2025.02.083

Abstract

Abstract: A novel, high strength, low modulus, and ductile metastable β Ti-14Nb-6Zr-3Fe (TNZF) alloy was manufactured via laser powder bed fusion (LPBF) in-situ alloying. Process parameter optimization resulted in near-fully dense samples (< 0.1% porosity) under optimal conditions. The microstructure and mechanical properties of TNZF alloy were then tailored using two chessboard scanning strategies and a simple scanning strategy. Samples fabricated using the chessboard scanning strategy (CS-TNZF) benefited from a lower thermal gradient, the high growth restriction factor associated with the addition of Fe, and constitutional supercooling around residual Nb particles, resulting in a near-equiaxed grain structure (average aspect ratio: 2.0) compared to the AS-TNZF (fabricated using the simple scanning strategy). The microstructure consisted of a β-Ti matrix with 2-5 nm sized ω precipitates. Due to the addition of Zr, the transition from β to ω was suppressed during thermal cycling associated with LPBF, resulting in the presence of a partially collapsed ω phase. Without post-processing heat treatments, the AS-TNZF condition exhibited a yield strength (YS) of 1091 MPa, an elastic modulus (E) of 68 GPa, and an elongation (EL) of 16.8%, while the CS-TNZF counterpart achieved a higher YS of 1147 MPa and E of 71 GPa, but a lower EL of 10.8% due to a higher volume fraction of ω phase. Both AS-TNZF and CS-TNZF demonstrated high elastic admissible strain values (YS/E ratio) of 1.60 and 1.62, respectively, achieving high strength, low modulus, and good ductility, which indicates their suitability for biomedical implant materials.

Key words: Laser powder bed fusion, High strength, Low modulus, Metastable β titanium alloy, In-situ alloying

Yue Li, Liuyong Wang, Haoyue Wu, Feng Ding, Min Lei, Jin Yang, J.P. Oliveira, Ming Yan, Wei Guo, Yulong Li. High strength, low modulus, and ductile metastable beta Ti-Nb-Zr-Fe alloys by laser powder bed fusion in-situ alloying[J]. J. Mater. Sci. Technol., 2026, 241: 270-283.

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