Laser Powder Bed Fusion of Beta-Type Titanium Alloys for Biomedical Application: A Review

doi:10.1007/s40195-023-01654-0

Abstract

Abstract:

Additive manufacturing of β-type titanium alloy is expected to replace Ti-6Al-4V alloy in the field of orthopedic implantation because of their low elastic modulus, excellent corrosion resistance, and biocompatibility. After briefly introducing the laser powder bed fusion (LPBF) process and physical phenomena, this paper reviews the recent progresses in LPBF-ed β-type Ti alloys. The strategies to strengthening and toughening β-type Ti alloys are critically reviewed. This is followed by the processing routes employed to achieve to low modulus for orthopedic applications, especially a new methodology for tailoring crystallographic orientation called multi-track coupled directional solidification. The effect of processing and compositions on performance metrics of β-type Ti alloys included corrosion behavior, and biocompatibility is reviewed. In the end, challenges in additive manufacturing of β-type Ti alloys in future are highlighted, with the aim to ensue clinical application of LPBF-ed β-type Ti alloys.

Key words: β-type Ti alloys, Laser powder bed fusion, Mechanical properties, Elastic modulus, Biocompatibility

Xuan Luo, Chao Yang, Dongdong Li, Lai-Chang Zhang. Laser Powder Bed Fusion of Beta-Type Titanium Alloys for Biomedical Application: A Review[J]. Acta Metallurgica Sinica (English Letters), 2024, 37(1): 17-28.

Figures/Tables 7

Fig. 1 Dominant physical phenomena during melting [45]

Fig. 2 a A schematic represents in situ heat treatment during the laser remelts; b a 3D morphology of LPBF-ed Ti–12Mo–6Zr–2Fe sample; c bright-field TEM image of a selected area containing α″ phase; d the SAED pattern along the [$\overline{1 }$11]β zone axis collected from the black dotted circle in c showing the orientation relationship of [$\overline{1 }$10]α″//[$\overline{1 }$11]β; e–h EDX elemental maps of Ti, Mo, Zr, and Fe collected from c, respectively; i the engineering (solid lines) and true (dotted lines) stress–strain curves of as-fabricated simple-scanned (AF-SS), (chess-scanned) AF-CS, and (solution heat-treated chess-scanned) ST–CS Ti–12Mo–6Zr–2Fe alloys [61]

Fig. 3 Lamellar mechanical twins in LPBF-ed Ti-35Nb-7Zr-5Ta alloy before a, b and after c, d deformation, e schematic illustration of interaction mechanism between twin and dislocation during tensile deformation, f tensile yield strength vs elongation of the Ti-35Nb-7Zr-5Ta alloy samples and other representative β-Ti alloys fabricated by various materials processing methods [28]

Fig. 4 a Schematic diagram of microstructure evolution and globularization mechanism with different heat treatment times, TEM morphology of the LPBF-ed b and heat-treated c Ti-Nb-Zr-Ta-Si alloys, d yield strength and elongation to failure of Ti-Nb-Zr-Ta alloys and Ti-Nb-Zr-Ta-Si alloys [65]

Fig. 5 a, c Inverse pole figure (IPF) images taken in the three orthogonal planes. b, d $\left\{001\right\}$ and $\left\{011\right\}$ pole figures of the products measured in the y–z plane [84]

Fig. 6 a Schematic of MTCDS technique. Points B and E are the intersections between the top and bottom layers. Points B and C are the intersections between the left and right adjacent melt pools. The melt pool angle θ is the angle between line CD and the horizontal direction. The columnar grain angle α is the angle between the GDCG and the horizontal direction. The TGD is normal to the melt pool boundary and approximately normal to line CD. b, c SEM and EBSD images of single melt track. d-g Inverse pole figure and h-k 〈001〉 pole figure of 〈001〉 dendrites with different spatial orientation. l The elastic modulus along the construction direction with the 〈001〉 crystallographic orientation. m Letters S, C, U, and T produced by scanning speeds of 600, 800, 1000, and 1400 mm/s, respectively, exhibiting different deviation angles relative to the building direction. The surrounding matrix is produced at the scanning speed of 1400 mm/s [96]

Fig. 7 Corrosion behavior and characteristics of passive films of laser powder bed fusion produced Ti-6Al-4V in static and dynamic Hank’s solution [100]

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