Metal Matrix Composites

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Mg-3Al-0.4Ce alloy; nano ZnO particles; uniform distribution; strength; titanium matrix composite; constitutive model; interfacial debonding; high temperature; elastoplastic properties; nano-sized SiCp; aluminum matrix composites; mechanical properties; microstructures; Mg–Al–RE alloy; magnesium alloy; damping; Al₁₁La₃ phase; nanosize reinforcement; mechanical properties; spark plasma sintering; Cu–TiC; in-situ composites; mechanical milling; iron aluminum alloys; cold/hot PM; compressibility factor; wear resistance; Al-Zn-Cr alloys; powder metallurgy; strengthening; extrusion; dry sliding wear; synthesis of core–shell metal nanoparticles; Cu@Ag composite nanoparticle; metal mesh; screen printing; touch screen panel; tungsten composites; tungsten-fibre-net reinforcement; powder metallurgy; tensile strength; metal matrix composites; nickel; aluminum; carbon nanotubes; powder metallurgy; ultrasonication; microstructural characterization; Magnesium; Sm₂O₃ nanoparticles; compression properties; damping; microstructure; ignition; carbon nanotube; nanocomposite; dispersion; interfacial adhesion; phase transformation; physicomechanical properties; nanoparticles; metal matrix nanocomposite (MMNC); AlN; magnesium alloy AM60; strengthening mechanisms; in situ titanium composites; microstructure analysis; TiB precipitates; metal matrix composites; 7075 Al alloy; reduced graphene oxide; mechanical properties; strengthening mechanism; metal matrix nanocomposite; copper; graphene; dispersion; powder metallurgy; thermal expansion coefficient; thermal conductivity; electrical resistance; thixoforging; magnesium-based composite; fracture; magnesium-alloy-based composite; Halpin-Tsai-Kardos model; deformation behavior; composite strengthening; fracture behavior; magnesium; high entropy alloy; composite; hardness; compressive properties; magnesium; tricalcium phosphate; compression; damping; corrosion; powder metallurgy; n/a