Vortex jets generated by edge defects in current-carrying superconductor thin strips
Abstract
At sufficiently large transport currents , a defect at the edge of a superconducting strip acts as a gate for the vortices entering into it. These vortices form a jet, which is narrow near the defect and expands due to the repulsion of vortices as they move to the opposite edge of the strip, giving rise to a transverse voltage . Here, relying upon the equation of vortex motion under competing vortex-vortex and -vortex interactions, we derive the vortex jet shapes in narrow () and wide () strips [: coherence length, : strip width, : effective penetration depth]. We predict a nonmonotonic dependence which can be measured with Hall voltage leads placed on the line at a small distance apart from the edge defect and which changes its sign upon reversal. For narrow strips, we compare the theoretical predictions with experiment, by fitting the data for m-wide MoSi strips with single edge defects milled by a focused ion beam at distances -\,nm from the line . For wide strips, the derived magnetic-field dependence of the vortex jet shape is in line with the recent experimental observations for vortices moving in Pb bridges with a narrowing. Our findings are augmented with the time-dependent Ginzburg-Landau simulations which reproduce the calculated vortex jet shapes and the maxima. Furthermore, with increase of , the numerical modeling unveils the evolution of vortex jets to vortex rivers, complementing the analytical theory in the entire range of .
Cite
@article{arxiv.2204.06467,
title = {Vortex jets generated by edge defects in current-carrying superconductor thin strips},
author = {A. I. Bezuglyj and V. A. Shklovskij and B. Budinska and B. Aichner and V. M. Bevz and M. Yu. Mikhailov and D. Yu. Vodolazov and W. Lang and O. V. Dobrovolskiy},
journal= {arXiv preprint arXiv:2204.06467},
year = {2022}
}
Comments
12 pages, 6 figures