Effect of carbonaceous reinforcements on the mechanical and tribological properties of friction stir processed Al6061 alloy

Abstract

Aluminum alloy (Al6061) is an eminent aerospace and automotive material, but its poor wear-resistance can be circumvented by friction stir process (FSP) via microstructural modification. Herein, carbonaceous particles (graphite, carbon nanotubes and graphene) are reinforced in order to assess their effect on mechanical and tribological properties of FSP Al6061. Raman spectroscopy has indicated the retention of damaged carbonaceous product in the stir zone due the intense plastic deformation and shear stresses involved in the FSP. Damage of carbonaceous particles was further confirmed from the transmission electron microscopy. Surface peak-hardness was observed to increase (~1.3GPa) for graphene reinforced composite when compared to that of untreated Al6061 (~0.5GPa) due to grain refinement (50–100nm). A substantial reduction in Hertzian-contact-diameter from 117μm in unprocessed Al6061 alloy to 103μm upon graphene reinforcement, has ensued least wear volume (0.03×10−3mm3) compared to that of untreated Al6061 alloy (~0.1903×10−3mm3). Self-lubricating nature of carbonaceous material has indicated lower frictional force and dominance of gross-slip regime with graphene reinforcement in FSP Al6061 when compared to that of stick-slip wear damage in untreated Al6061.