Additive manufacturing (AM) of metals is rapidly emerging as an established manufacturing
process for metal components. Unlike traditional metals fabrication processes, metals …

Additive manufacturing (AM) promises a major transformation for manufacturing of metallic
components for aerospace, medical, nuclear, and energy applications. This perspective …

Fusion-based additive manufacturing technologies enable the fabrication of geometrically
and compositionally complex parts unachievable by conventional manufacturing methods …

Metal additive manufacturing (AM) works on the principle of incremental layer-by-layer
material consolidation, facilitating the fabrication of objects of arbitrary complexity through …

The properties and serviceability of 3D-printed metal parts depend on a variety of attributes.
These include the chemical composition, phases, morphology, spatial distributions of grain …

Metal additive manufacturing (AM) has now become the perhaps most desirable technique
for producing complex shaped engineering parts. However, to truly take advantage of its …

Additive manufacturing of metallic alloys involves non-uniform temperature distributions and
rapid thermal cycles that result in microstructures featured with anisotropy, which differ …

A computational model was developed to predict solid-state phase transformation kinetics
within mechanical parts during metal additive manufacturing processes. This model is a …

As a revolutionary industrial technology, additive manufacturing creates objects by adding
materials layer by layer and hence can fabricate customized components with an …

Titanium alloys are used in a wide variety of high-performance applications and hence the
processing of titanium and the resulting microstructures after additive manufacturing has …