Nanoparticle interactions with the magnesium alloy matrix during physical deformation: Tougher nanocomposites

This study is aimed at understanding the toughness enhancing function of nanoparticles in magnesium nanocomposites, focussing on experimentally observed nanoparticle–matrix interactions during physical deformation. Al2O3 nanoparticles were selected for reinforcement purposes due to the well known affinity between magnesium and oxygen. AZ31/AZ91 (hybrid alloy) and ZK60A magnesium alloys were reinforced with Al2O3 nanoparticles using solidification processing followed by hot extrusion. In tension, each nanocomposite exhibited higher ultimate strength and ductility than the corresponding monolithic alloy. However, the increase in ductility exhibited by ZK60A/Al2O3 (+170%) was significantly higher than that exhibited by AZ31/AZ91/Al2O3 (+99%). The previously unreported and novel formation of high strain zones (HSZs, from nanoparticle surfaces inclusive) during tensile deformation is highlighted here as a significant mechanism supporting ductility enhancement in ZK60A/Al2O3 (+170% enhanced) and AZ31/AZ91/Al2O3 (+99% enhanced) nanocomposites. Also, ZK60A/Al2O3 exhibited lower and higher compressive strength and ductility (respectively) compared to ZK60A while AZ31/AZ91/Al2O3 exhibited higher and unchanged compressive strength and ductility (respectively) compared to AZ31/AZ91. Here, the previously unreported nanograin formation (recrystallization) during room temperature compressive deformation as a toughening mechanism in relation to nanoparticle stimulated nucleation (NSN) ability is also highlighted.