Mechanical Strength and Electrical Conductivity of Cu-In Solid Solution Alloy Wires

Conductive spring wires for application in electrical components require high strength, high electrical conductivity, and convenient manufacturability. Copper-indium (Cu-In) solid solution alloys are suitable candidates for such wires because they exhibit effective solid solution strengthening without significantly decreasing the conductivity. Herein, we systematically investigate the microstructure of Cu-In alloy wires fabricated by severe drawing, along with their mechanical and electrical properties. During the initial drawing stages, high-density deformation twins are generated in the Cu-In alloy because the In solute efficiently reduces the stacking fault energy (SFE) of the Cu matrix. These deformation twins promote grain refinement during subsequent drawing. The Cu-5.0 at. pct In alloy wire, drawn severely to an equivalent strain of 4.61, possesses ultrafine grains measuring 60 to 80 nm with a high density of dislocations, resulting in excellent yield strength, tensile strength, and conductivity of 1280 MPa, 1340 MPa, and 24 pct relative to the International Annealing Cu Standard, respectively. These properties were comparable to those of age-hardenable Cu-Be and Cu-Ti alloys; thus, our results demonstrate that tuning the In content of the Cu matrix to reduce the SFE and optimizing the deformation strain to refine the grain size significantly improves the performance of alloy wires.

Automated summary

Copper-indium (Cu-In) solid solution alloys exhibit effective solid solution strengthening without significantly decreasing the conductivity, making them suitable candidates for conductive spring wires. In this study, we investigated the microstructure, mechanical properties, and electrical properties of Cu-In alloy wires fabricated by severe drawing. It was found that high-density deformation twins were generated in the Cu-In alloy during the initial drawing stages, promoting grain refinement. The Cu-5.0 at. pct In alloy wire, drawn severely to an equivalent strain of 4.61, possessed ultrafine grains with excellent yield strength, tensile strength, and conductivity.