The application of additively manufactured (AM) stainless steel (SS) parts is rapidly
emerging in a broad spectrum of industries. Laser powder bed fusion (LPBF) and direct …

Low-temperature decomposition of supersaturated solid solution into unfavorable
intergranular precipitates is a long-standing bottleneck limiting the practical applications of …

The hierarchical nature of additively manufactured materials necessitates a multimodal
approach for quantifying microstructural features and corresponding chemical …

A high density of lattice defects is introduced to materials by severe plastic deformation
(SPD). Numerous experimental techniques, in particular electron microscopy, X-ray, electron …

The microstructural evolution and deformation mechanisms of 316L stainless steel
fabricated by Selective Laser Melting (SLM) and then processed by high-pressure torsion …

Herein, in situ temperature‐dependent neutron experiments investigate the microstructural
evolution of additively and conventionally manufactured CoCrFeNi high‐entropy alloys, as …

Material Extrusion (ME) multi-step additive manufacturing of highly filled metal filament
Ultrafuse 316L offers a notable alternative to cutting-edge additive technologies of metal …

One of the key goals of processing 316L stainless steel by powder metallurgy (PM)
techniques is to achieve industrial-viable tensile properties without structural defects like …

Despite their good corrosion resistance and optimal mechanical properties, duplex stainless
steels are affected by hydrogen embrittlement. Therefore, understanding the hydrogen …

Processing of metallic materials by Severe Plastic Deformation (SPD) leads to the formation
of many lattice defects (eg, vacancies, dislocations, twin faults and grain boundaries). In this …