Microstructural and mechanical properties of Ti-Mo alloys designed by the cluster plus glue atom model for biomedical application

β-type titanium alloys are acquiring research interest in orthopaedic applications because of their exceptional properties such as moderate strength, good biocompatibility and corrosion resistance, high ductility and low elastic modulus. The study aims at designing a series of binary Ti-Mo alloys (T...

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Bibliographic Details
Published in:International journal of advanced manufacturing technology 2020-11, Vol.111 (5-6), p.1237-1246
Main Authors: Moshokoa, Nthabiseng, Raganya, Lerato, Obadele, Babatunde Abiodun, Machaka, Ronald, Makhatha, Mamookho Elizabeth
Format: Article
Language:English
Subjects:
Austenitic stainless steels
Beta phase
Binary alloys
Biocompatibility
Biomedical materials
CAE) and Design
Casting alloys
Chromium
Clusters
Computer-Aided Engineering (CAD
Corrosion resistance
Diamond pyramid hardness
Electron back scatter
Elongation
Engineering
Industrial and Production Engineering
Mechanical Engineering
Mechanical properties
Media Management
Microscopy
Microstructure
Modulus of elasticity
Molybdenum
Optical microscopy
Original Article
Orthopaedic implants
Orthopedics
Strain
Surgical implants
Tensile properties
Tensile strength
Tensile tests
Titanium alloys
Titanium base alloys
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Summary:β-type titanium alloys are acquiring research interest in orthopaedic applications because of their exceptional properties such as moderate strength, good biocompatibility and corrosion resistance, high ductility and low elastic modulus. The study aims at designing a series of binary Ti-Mo alloys (Ti-8.71 Mo, Ti-10.02 Mo, Ti-11.78 Mo and Ti-15.05 Mo (wt%)) using the cluster plus glue atom model to design the compositions. The prediction methods such as the molybdenum equivalence, the average electron ratio and the d-electron methods were used to predict the stability of the β phase. Microstructural evolution and phases of the designed alloys were characterized using the optical microscopy (OM), scanning electron microscopy (SEM), electron backscatter diffractometry (EBSD) and X-ray diffractometry (XRD), while the microhardness and tensile properties were measured using the Vickers hardness tester and tensile testing machine. The microstructure of the cast Ti-Mo alloys comprised primarily the β phase and secondary orthorhombic martensitic α″ and athermal omega (ω) phases. Their elastic moduli (96.8–70.5 GPa) decreased with the amount of Ti in the glue side and were found to be lower than the commercially available 316 L stainless steel, Co-Cr and Ti6Al4V alloys. The microhardness values of the as-cast Ti-Mo alloys decreased as the amount of Ti in the glue side decreased in the cluster formula. The tensile strength of the as-cast alloys ranges from 796.76 to 593.48 MPa with Ti-8.71 wt% Mo alloy showing the highest tensile strength owing to the amount of Ti in the glue side. The yield strength of all the designed alloys decreased as the amount of Ti atoms placed in the glue side decreased. The elongation at fracture ranged between 0.28 and 0.71%, indicating that all the designed alloys fractured in a brittle manner. The elastic admissible strain of the designed alloys (Ti-15.05 wt% Mo) was significantly higher than the conventional orthopaedic implant materials (CP-Ti, Ti6Al4V) indicating that this study is promising for the development of excellent biomedical materials.
ISSN:0268-3768
1433-3015
DOI:10.1007/s00170-020-06208-7