The growth and development in the biomedical field are very essential for the sustainable
and holistic well-being of our entire society. The shortage of patient-specific products is the …

Lattice structures are composed of interconnected porous unit cells that are arranged in a
periodic and regular fashion. Their light wight and high specific strength alongside many …

Metallic cellular solids, made of biocompatible alloys like titanium, stainless steel, or cobalt-
chromium, have gained attention for their mechanical strength, reliability, and …

Titanium and its alloys are potential materials for orthopedic implant applications due to their
appropriate biological and mechanical behavior. As biocompatibility and biomechanical …

Currently, the numerical simulation of final 3D parts obtained by additive manufacturing (AM)
using the selective laser melting (SLM) and the electron beam melting (EBM) techniques is …

It is well established in literature that, when processing intermetallic γ-TiAl components by
electron beam powder bed fusion, a banded microstructure is frequently formed because of …

Although titanium is widely used as biomaterial, the control of the interface properties
between its surface and the surrounding physiological environment (like bone, other tissues …

As a novel structural and functional material, porous titanium and its alloys have been widely
used in the aerospace, marine engineering and biomedical fields due to their high corrosion …

One of the vital parameters of the additive manufacturing (AM) process is the scanning
strategy. In this article, advanced joint path strategies based on irregular hexahedrons …

Titanium alloy is a typical difficult-to-machine material with features of superhigh strength
and hardness, and low elastic modulus. It is difficult to guarantee the processing quality and …