The development of materials for biomedical, aerospace, and automobile industries has
been a significant area of research in recent years. Various metallic materials, including …

Additive manufacturing (AM) is an innovative technology that creates objects with a complex
geometry layer-by-layer, and it has rapidly prospered in manufacturing metallic parts for …

It is easy to understand why industry and, especially, aerospace engineers love titanium.
Titanium parts weigh roughly half as much as steel parts, but its strength is far greater than …

The most popular additive manufacturing (AM) technologies to produce titanium alloy parts
are electron beam melting (EBM), selective laser melting (SLM) and directed energy …

Titanium‐based orthopedic implants are increasingly being fabricated using additive
manufacturing (AM) processes such as selective laser melting (SLM), direct laser deposition …

The results of untiring efforts by the research community over the past few decades have led
to the successful development and processing of a number of advanced titanium alloys with …

The directed energy deposition (DED) process can be employed to build net shape
components or prototypes starting from powder or wires, through a layer-by-layer process …

This paper describes the state of the art of additive manufacturing of Titanium alloys
especially in the high-value-materials industries such as aerospace and biomedical. In such …

Titanium and its alloys have been widely used for biomedical applications due to their better
biomechanical and biochemical compatibility than other metallic materials such as stainless …

Manufacturing titanium aluminides (TiAls) parts are challenging due to their low ductility and
fracture toughness. However, processing these materials is of significant interest for …