Structure and Mechanical Properties of Transition Group Metals, Alloys, and Intermetallic Compounds

© 2019 by the authors; CC BY-NC-ND license

metal matrix composites; laser metal deposition; Inconel 625; additive manufacturing; laser processing; metal matrix composites; Z-pin reinforcement; delamination; carbon fiber; strengthening mechanisms; severe plastic deformation (SPD); cross-channel extrusion (CCE); back pressure (BP); numerical simulation (FEM); physical modeling technique (PMT); metal–matrix composites (MMCs); carbon fiber; mechanical properties; z-pin reinforcement; laminate; titanium alloys; high pressure torsion; microhardness; Cu–Ag alloy; high-pressure torsion; ultrafine microstructure; phase dissolution; microhardness; friction stir welding; heat treatment; AA2519; microstructure; fatigue; fractography; AZ91; magnesium alloys; creep; high pressure die casting; additive manufacturing; Ti-6Al-4V; LENS; mechanical characterization; twin roll casting; magnesium alloy; calcium; Mg-Zn-Al-Ca alloy; texture; flow curve; processing map; honeycomb structure; additive manufacturing; laser engineered net shaping; LENS; Ti6Al4V alloy; energy absorption; dynamic tests; solidification thermal parameters; Cu-Al-Ni-Fe bronze alloys; hardness; microhardness; specific intermetallics; MAX phase; Ti₃SiC₂; composite; high energy ball milling; spark plasma sintering; structure; mechanical properties; deformation behavior; tribaloy-type alloy; CoCrMoSi alloy coatings; T-800 alloy; Laves phase; Laser Engineered Net Shaping (LENS^TM); electron microscopy (in situ SEM); delamination; metal matrix composites (MMCs); z-pinning