Abstract To engineer a Cu–Ti based alloy with titanium-and oxygen-free copper matrix using commercially-feasible powders, an in situ hydrogenation – re-oxidation approach was suggested and supported by grand potential diagram… Click to show full abstract
Abstract To engineer a Cu–Ti based alloy with titanium-and oxygen-free copper matrix using commercially-feasible powders, an in situ hydrogenation – re-oxidation approach was suggested and supported by grand potential diagram mapping of Cu–Ti–O–H system. Reactive composite powders with nominal composition Cu–10%TiH2, containing 7% native Cu2O, were manufactured by high energy ball milling. The phase and structure formation mechanisms were experimentally investigated by DSC, in situ XRD, SEM, and HRTEM. Multi-stage phase formation mechanism involving decomposition of TiH2, reduction of Cu2O by the released H2, formation of water vapor and re-oxidation of Ti upon cooling leads to the formation of hierarchically-structured copper alloy, reinforced by micron- and nanosized (5–30 nm) Cu3Ti3O precipitates. Due to the metallic nature of Cu3Ti3O and its coherent precipitation from the copper matrix, as well as to the inhibition of Ti dissolution in Cu, the developed alloy demonstrates high yield strength (910 ± 30 MPa) and electrical conductivity (2.6∙107 Sm/m, 42% of International Annealed Copper Standard), comparable to the cold-worked and peak-aged Cu–Be and Cu–Ti bronzes.
               
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