Improved mechanical properties in titanium matrix composites reinforced with quasi-continuously networked graphene nanosheets and in-situ formed carbides

In order to construct quasi-continuously networked reinforcement in titanium (Ti) matrix composites, in this study, Ti-6Al-4V spherical powders were uniformly coated with a graphene nanosheet (GNS) layer by high energy ball milling and then consolidated by spark plasma sintering. Results showed that the GNS layer on the powder surface inhibited continuous metallurgy bonding between powders during sintering, which led to the formation of quasi-networked hybrid reinforcement structure consisting of insitu TiC and remained GNSs. The networked GNSs/Ti64 composite possessed noticeably higher tensile strength but similar ductility to the Ti64 alloy, leading to both better tensile strength and ductility than the GNSs/Ti composite with randomly dispersed GNSs and TiC. The formation mechanism and the fracture mechanism of the networked hybrid reinforcement were discussed. The results provided a method to fabricate Ti matrix composites with high strength and good ductility. (c) 2022 Published by Elsevier Ltd on behalf of The editorial office of Journal of Materials Science & Technology.

Automated summary

A quasi-networked reinforcement structure in titanium matrix composites was achieved by uniformly coating Ti-6Al-4V spherical powders with a graphene nanosheet layer, leading to higher tensile strength and good ductility compared to randomly dispersed graphene nanosheets and TiC. The study provided a method to fabricate titanium matrix composites with high strength and good ductility by forming a networked hybrid reinforcement structure.