Effect of hole pattern on high temperature superconducting wire using metal stitching for high-speed quench propagation

In this study, we investigated the influence of hole pattern on the quench propagation behavior of high-temperature superconducting (HTS) wires utilizing a metal stitching technique. A nano-second laser processing system was used to fabricate precise micro-hole patterns through the metal and insulation layers of the HTS conductor. To evaluate the quench performance, HTS wires were prepared with various hole spacing patterns (5  cm, 2.5  cm, and 1  cm) and compared with an unmodified original wire. The results showed that as the hole spacing decreased, the decay of the central magnetic field after quench became significantly faster. In particular, the sample with 2.5  cm spacing exhibited a sharp drop in central field from 44 G to 3 G after quench. Additionally, a metal-insulated coil incorporating a 2  cm-spacing metal stitching pattern demonstrated a magnetic flux density decay rate exceeding 40 G/sec, indicating improved responsiveness in quench detection and protection systems. These findings confirm the potential of metal stitching as a structural strategy to enhance the quench safety in HTS applications.