Additive manufacturing of industrially-relevant high-performance parts and products is today
a reality, especially for metal additive manufacturing technologies. The design complexity …

Additive manufacturing (AM) is a digital manufacturing technology, rapidly revolutionizing in
the medical sectors for printing of distinct body parts having intrinsic shapes and offering …

Metal additive manufacturing (AM) has developed rapidly over the last decade to become a
disruptive technology capable of revolutionizing the way that products from various industrial …

Commercially pure titanium (CP–Ti) gyroid scaffolds with interconnected pores and high
porosities in the range of 68–73% and three different unit cell sizes of 2, 2.5, and 3 mm were …

In metal additive manufacturing (AM), long columnar grains along the building direction due
to highly directional thermal gradients often lead to a strong texture and severe anisotropy in …

Additive manufacturing (AM), often termed 3D printing, has recently emerged as a
mainstream means of producing metallic components from a variety of metallic alloys. The …

Abstract Ti-6Al-4V gyroid scaffolds with high porosities in the range of 82–85% and three
different unit cell sizes 2, 2.5 and 3 mm were manufactured by electron beam melting (EBM) …

The geometry and material properties of additively manufactured (AM) parts are closely
related in a way that any alteration in geometry of the part will change the underlying …

Electron beam melting (EBM) is a rapidly-developing metal additive manufacturing process
that holds significant interest in the aerospace and biomedical industries for the high …

Additive layer manufacturing (ALM), using gas tungsten arc welding (GTAW) as heat source,
is a promising technology in producing Inconel 625 components due to significant cost …