Vortex confinement through an unquantized magnetic flux

TL;DR

This paper demonstrates that magnetic flux confinement can occur in superconductors regardless of their dimensionality, revealing a universal phenomenon of unquantized magnetic flux formation with implications for low-dimensional superconductors.

Contribution

The study experimentally shows unquantized magnetic flux confinement in 1D and 2D superconductors using a magnetic force microscope, extending understanding of flux behavior beyond traditional quantization.

Findings

Creation of a vortex-antivortex pair connected by unquantized flux

Observation of long-range interaction mediated by unquantized flux

Universal flux confinement independent of system geometry

Abstract

Geometrically confined superconductors often experience a breakdown in the quantization of magnetic flux owing to the incomplete screening of the supercurrent against the field penetration. In this study, we report that the confinement of a magnetic field occurs regardless of the dimensionality of the system, extending even to 1D linear potential systems. By utilizing a vector-field magnetic force microscope, we successfully create a vortex-antivortex pair connected by a 1D unquantized magnetic flux in ultra-thin superconducting films. Through an investigation of the manipulation and thermal behavior of the vortex pair, we uncover a long-range interaction mediated by the unquantized magnetic flux. These findings suggest a universal phenomenon of unquantized magnetic flux formation, independent of the geometry of the system. Our results present an experimental route for probing the impact of confinement on superconducting properties and order parameters in unconventional superconductors characterized by extremely low dimensionality.