Magnetically Induced Switching-Current Jumps in InAs/Al Josephson Junctions
Abstract
We report Barkhausen-like switching at millitesla fields in an n-doped InAs/Al nanowire Josephson junction, which serves as an interferometric probe of intrinsic magnetic reconfigurations, as evidenced by discrete switching-current jumps. At T=30~mK the device displays a Fraunhofer-like modulation with Isw(0)≈ 0.24~μA and an abrupt transition at |B|≈ 3~mT between two branches differing by Isw≈ 0.13~μA. By tracking the characteristic field scales from 30 to 900~mK, we find that the jump field is essentially temperature-independent, whereas the superconducting critical field decreases with temperature, as expected for thin Al films. The sharp discontinuity, sweep-direction asymmetry, and reproducibility across repeated scans point to avalanche-like switching between metastable magnetic configurations of the local magnetic texture, which are directly coupled to the weak link. Within an effective-field framework, each reconfiguration modifies a local field offset, thereby reshaping the interference response and leading to an abrupt reorganization of the switching-current pattern.
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