Titanium (Ti) and its alloys are widely used for medical and dental implant devices—artificial
joints, bone fixators, spinal fixators, dental implant, etc.—because they show excellent …

Metal additive manufacturing (AM) is an innovative manufacturing technique, which builds
parts incrementally layer by layer. Thus, metal AM has inherent advantages in part …

Abstract Metastability-engineering, eg, transformation-induced plasticity (TRIP), can
enhance the ductility of alloys, however it often comes at the expense of relatively low yield …

ABSTRACT A new bcc Ti-rich high-entropy alloy (HEA) of composition Ti35Zr27. 5Hf27.
5Nb5Ta5 was designed using the 'd-electron alloy design'approach. The tensile behavior …

Metastable β titanium alloys possess excellent strain-hardening capability, but suffer from a
low yield strength. As a result, numerous attempts have been made to strengthen this …

Metastable β titanium alloys usually suffer from relatively low yield strengths, which restricts
their applications as a structural material. Additive manufacturing (AM), due to its extremely …

Metastable β Ti alloys are widely projected for manufacturing the next generation of
biomedical implants. The primary applications of these materials are envisaged in …

Refractory high‐entropy alloys (RHEAs) inspire the development of novel high‐temperature
structural materials due to their outstanding resistance to softening and phase stability at …

In metastable β-Ti alloys, the primary deformation mechanisms, including ordinary
dislocation plasticity (ODP), deformation twinning (DT), and phase transformation, are …

Abstract Biomedical β-phase Ti-Nb-Ta-Zr alloys usually exhibit low elastic modulus with
inadequate strength. In the present work, a series of newly developed dual-phase Ti-xNb …