Effect of Low Annealing Temperature on the Critical-Current Density of 2% C-Doped MgB(2) Wires Used in Superconducting Coils with the Wind-and-React (W&R) Method—High-Field and High-Temperature Pinning Centers

The use of a low annealing temperature during the production of coils made from superconducting materials is very important because it reduces the production costs. In this study, the morphology, transport critical-current density (J(c)), irreversible magnetic field (B(irr)), and critical temperature (T(c)) of straight wires and small 2% C-doped MgB(2) coils were investigated. The coils were made using the wind-and-react (W&R) method and annealed at various temperatures from 610 °C to 650 °C for 2–12 h. Critical-current measurements were made for both the coils and straight wires at the temperatures of 4.2 K, 20 K, 25 K, and 30 K. During our research study, we determined the process window that provides the best critical parameters of the coils (annealing at a temperature of 650 °C for 6 h). Moreover, we observed that small coils made with unreacted MgB(2) wire and then annealed had morphology and critical parameters similar to those of straight 2% C-doped MgB(2) wires. Moreover, small-diameter bending of 20 mm and 10 mm did not lead to transverse cracks, which can cause a large reduction in J(c) in the coils. This indicates that the processes of optimization of thermal treatment parameters can be carried out on straight MgB(2) wires for MgB(2) superconducting coils.