Rising speed limits for fluxons via edge quality improvement in wide MoSi thin films

Abstract

Ultra-fast vortex motion has recently become a subject of extensive investigations, triggered by the fundamental question regarding the ultimate speed limits for magnetic flux quanta and enhancements of single-photon detectors. In this regard, the current-biased quench of a dynamic flux-flow regime - flux-flow instability (FFI) - has turned into a widely used method for the extraction of information about the relaxation of quasiparticles (unpaired electrons) in the superconductor. However, the large relaxation times τε deduced from FFI for many superconductors are often inconsistent with the fast relaxation processes implied by their single-photon counting capability. Here, we investigate FFI in 15 nm-thick 182 μm-wide MoSi strips with rough and smooth edges produced by laser etching and milling by a focused ion beam. For the strip with smooth edges we deduce, from the current-voltage (I-V) curve measurements, a factor of 3 larger critical currents Ic, a factor of 20 higher maximal vortex velocities of 20 km/s, and a factor of 40 shorter τε. We argue that for the deduction of the intrinsic τε of the material from the I-V curves, utmost care should be taken regarding the edge and sample quality and such a deduction is justified only if the field dependence of Ic points to the dominating edge pinning of vortices.