The use of biomedical metallic materials in research and clinical applications has been an
important focus and a significant area of interest, primarily owing to their role in enhancing …

Exciting metallurgical breakthroughs of the last decades alongside the development and
wide-ranging availability of new and more capable experimental and theoretical tools for …

High strength and low elastic modulus are critical properties of biomedical titanium alloys for
manufacturing of load-bearing orthopaedic implants. Single phase beta Ti alloys can …

The current understanding of room temperature microplasticity in α/β titanium alloys is
reviewed with a special emphasis on dual-phase engineering alloys. As the interplay …

Abstract Ti-Nb based β-Ti alloys are a promising new class of superelastic, shape-memory,
and low-modulus materials for a wide range of applications. A critical phase in β-Ti alloys is …

Additive manufacturing of near β-type Ti-13Nb-13Zr alloys using the laser powder bed
fusion process (LPBF) opens up new avenues to tailor the microstructure and subsequent …

The optimal design of shape memory alloys (SMAs) with specific properties is crucial for the
innovative application in advanced technologies. Herein, inspired by the recently proposed …

On the basis of the “-Mo-Ti-Mo-” linear unit along the specific< 111> β,< 110> β, and< 100>
β directions, the cluster structures of α ″-martensite and ω-phase were constructed in …

Athermal pure shuffle O′ nanodomains have been reported as a common structural state in
metastable β-Ti alloys. In this study, by integrating thermodynamic databases, first-principles …

The demand for titanium alloys simultaneously having high elastic admissible strain and
large recovery strain for bio-implant applications is increasing. Ni-free Ti-based shape …