Saved in:
Bibliographic Details
Main Author: Shi, Ruby A.
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2505.13798
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866909616979312640
author Shi, Ruby A.
author_facet Shi, Ruby A.
contents In type-II superconductors, magnetic flux penetrates in the form of quantized vortices whose dissipative motion, driven by the Lorentz force, can degrade superconductivity. Understanding vortex dynamics in both homogeneous regions and near unavoidable structural defects is crucial for superconducting applications. This study examines a scenario in which a superconducting quantum interference device (SQUID) scans across a thin-film superconductor containing line defects. We first estimate the radial Lorentz force on a vortex in a homogeneous region using both analytical methods and numerical simulations based on the fast Fourier transform algorithm. For a film with a Pearl length of 400 micrometers and a SQUID height of 4 micrometers, we find that the SQUID tip can exert a force of approximately 3 femtonewtons on a vortex. We then evaluate the Lorentz force on vortices near two parallel line defects. Our results show that the Lorentz force is enhanced for vortices pinned on or between line defects. Vortices pinned on the line defects experience force enhancement predominantly perpendicular to the defects, while vortices in between experience enhancement along the defect direction. These findings enable more accurate estimation of Lorentz forces on vortices near line defects in thin-film superconductors and contribute to the broader understanding of vortex pinning and dynamics in defect-engineered superconductors. The methods can be extended to bulk superconductors and generalized to other defect geometries.
format Preprint
id arxiv_https___arxiv_org_abs_2505_13798
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Lorentz force on superconducting vortices near line defects
Shi, Ruby A.
Superconductivity
In type-II superconductors, magnetic flux penetrates in the form of quantized vortices whose dissipative motion, driven by the Lorentz force, can degrade superconductivity. Understanding vortex dynamics in both homogeneous regions and near unavoidable structural defects is crucial for superconducting applications. This study examines a scenario in which a superconducting quantum interference device (SQUID) scans across a thin-film superconductor containing line defects. We first estimate the radial Lorentz force on a vortex in a homogeneous region using both analytical methods and numerical simulations based on the fast Fourier transform algorithm. For a film with a Pearl length of 400 micrometers and a SQUID height of 4 micrometers, we find that the SQUID tip can exert a force of approximately 3 femtonewtons on a vortex. We then evaluate the Lorentz force on vortices near two parallel line defects. Our results show that the Lorentz force is enhanced for vortices pinned on or between line defects. Vortices pinned on the line defects experience force enhancement predominantly perpendicular to the defects, while vortices in between experience enhancement along the defect direction. These findings enable more accurate estimation of Lorentz forces on vortices near line defects in thin-film superconductors and contribute to the broader understanding of vortex pinning and dynamics in defect-engineered superconductors. The methods can be extended to bulk superconductors and generalized to other defect geometries.
title Lorentz force on superconducting vortices near line defects
topic Superconductivity
url https://arxiv.org/abs/2505.13798