Titanium (Ti) alloys are widely used in high-tech fields like aerospace and biomedical
engineering. Laser additive manufacturing (LAM), as an innovative technology, is the key …

Laser additive manufacturing (LAM) of titanium (Ti) alloys has emerged as a transformative
technology with vast potential across multiple industries. To recap the state of the art, Ti …

Growing maturity of SLM has enabled the use of rapid manufacturing technology on hard-to-
machine Ti alloys. In this review, selective laser melted titanium alloys are reviewed based …

Selective laser melting (SLM) technique is a prevalently used additive manufacturing (AM)
technology. In this paper, a comprehensive review focusing on the effect of the SLM process …

Additive Manufacturing (AM) is a rapid prototyping technique extensively used to build
complex structures and intricate shapes without the necessity of post process machining …

Titanium alloys are among the most extensively studied metallic materials in the broad
context of metal additive manufacturing (AM), and the last decade has seen increased niche …

The capability to control volume fraction and morphology of α phase in α+ β titanium alloys
makes this group of alloys a suitable choice to develop new compositions to deal with the …

As one of the most important additive manufacturing (AM) techniques, laser metal deposition
(LMD) has been extensively studied specially during the last few years. Similar to other AM …

Titanium alloys are highly adaptive to the manufacture of military, aircraft and medical
devices due to their high tensile strength and toughness. However, the traditional …

Metallic additive manufacturing, particularly selective laser melting (SLM), usually involves
rapid heating and cooling and steep thermal gradients within melt pools, making it extremely …