Superconducting Micro- and Nanohelices
Vladimir M. Fomin, Roman O. Rezaev, Evgenii A. Levchenko, Daniel Grimm, and Oliver G. Schmidt

TL;DR
This paper introduces superconducting micro- and nanohelices, analyzing their vortex patterns and state stability using the time-dependent Ginzburg-Landau theory, revealing controllable vortex configurations and a transition from tube-like to planar vortex patterns.
Contribution
First theoretical study of superconducting micro- and nanohelices, demonstrating vortex pattern control via geometric parameters and revealing a transition in vortex states.
Findings
Vortex patterns are controlled by helical stripe width and pitch.
Quasi-degeneracy occurs when vortex count is incommensurable with half-turns.
Transition from tube-like to planar vortex patterns with increasing radius.
Abstract
Superconducting micro- and nanohelices are proposed for the first time. A theoretical investigation of the superconducting state in the helical coils at the micro- and nanoscale is performed within the time-dependent Ginzburg-Landau approach. The pattern and number of vortices in a stationary distribution are determined by their confinement to the ultrathin helical spiral and can therefore be efficiently controlled by the helical stripe width and the helical pitch distance for both dense and sparse helices. Quasi-degeneracy of vortex patterns is manifested in the helical spiral when the number of vortices is incommensurable with the total number of half-turns. With increasing radius, superconducting helical spirals provide a physical realization of a transition from the vortex pattern peculiar to an open tube to that of a planar stripe.
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Taxonomy
TopicsPhysics of Superconductivity and Magnetism · Particle accelerators and beam dynamics · Superconductivity in MgB2 and Alloys
