Defect formation is a critical challenge for powder-based metal additive manufacturing (AM).
Current understanding on the three important issues including formation mechanism …

The use of biomedical metallic materials in research and clinical applications has been an
important focus and a significant area of interest, primarily owing to their role in enhancing …

In this work, NiTi shape memory alloys parts were additively manufactured using electron
beam freeform fabrication (EBF 3) under different processing parameters, including the …

NiTi alloys have drawn significant attentions in biomedical and aerospace fields due to their
unique shape memory effect (SME), superelasticity (SE), damping characteristics, high …

NiTi shape memory alloys (SMAs) are used in a broad range of biomedical applications
because of their unique properties including biocompatibility and high corrosion and wear …

Micro laser powder bed fusion (μLPBF) technology offers great benefits to industries as it
enables fabrication of complicated metallic components with greater accuracy and minimum …

NiTi alloy has a wide range of applications as a biomaterial due to its high ductility, low
corrosion rate, and favorable biocompatibility. Although Young's modulus of NiTi is relatively …

Micro laser powder bed fusion (µ-LPBF) additive manufacturing presents enormous
potential in fabricating complex metallic micro-components (ie the component with a feature …

In recent years, selective laser melting (SLM)-NiTi had developed rapidly due to the ability to
achieve the complex shape and internal features, as well as high dimensional accuracy. The …

Titanium matrix composites (TMCs) have gained tremendous attention due to their excellent
mechanical properties by combining the advantages of Ti6Al4V matrix and ceramic …