Saved in:
Bibliographic Details
Main Authors: Caputo, Jean-Guy, Rouxelin, Nathan
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2412.14691
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866910928720625664
author Caputo, Jean-Guy
Rouxelin, Nathan
author_facet Caputo, Jean-Guy
Rouxelin, Nathan
contents Type II superconductors can trap a transient magnetic field and become "cryomagnets" that are very useful for applications. During this process, flux jumps i.e. sudden jumps of the total magnetization occur and hinder the properties of these magnets. To understand the electrodynamics of these systems and in particular flux jumps, we analyzed mathematically a model based on Maxwell's equations and temperature in a 1D configuration. When a magnetic pulse is applied to a superconductor, three effects occur, from fastest to slowest: Joule heating, magnetic relaxation and temperature diffusion. Adimensionalising the problem, we obtain a nonlinear diffusion for the magnetic field coupled to a forced diffusion equation for the temperature with only two parameters. Two regimes occur, depending on temperature: for medium temperature the heat capacity of a sample can be assumed constant while for low temperature it depends on temperature causing a nonlinear temperature evolution. Flux jumps can be explained using the fixed points of the equations. We found that they occur for pulses of duration close to the magnetic relaxation time and mostly at low temperature because of the nonlinear dependance. Flux trapping is maximal for medium amplitude long duration pulses and low to medium temperatures, so these conditions are optimal to produce better cryomagnets.
format Preprint
id arxiv_https___arxiv_org_abs_2412_14691
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Mathematical analysis of a flux-jump model in superconductivity
Caputo, Jean-Guy
Rouxelin, Nathan
Superconductivity
Pattern Formation and Solitons
Type II superconductors can trap a transient magnetic field and become "cryomagnets" that are very useful for applications. During this process, flux jumps i.e. sudden jumps of the total magnetization occur and hinder the properties of these magnets. To understand the electrodynamics of these systems and in particular flux jumps, we analyzed mathematically a model based on Maxwell's equations and temperature in a 1D configuration. When a magnetic pulse is applied to a superconductor, three effects occur, from fastest to slowest: Joule heating, magnetic relaxation and temperature diffusion. Adimensionalising the problem, we obtain a nonlinear diffusion for the magnetic field coupled to a forced diffusion equation for the temperature with only two parameters. Two regimes occur, depending on temperature: for medium temperature the heat capacity of a sample can be assumed constant while for low temperature it depends on temperature causing a nonlinear temperature evolution. Flux jumps can be explained using the fixed points of the equations. We found that they occur for pulses of duration close to the magnetic relaxation time and mostly at low temperature because of the nonlinear dependance. Flux trapping is maximal for medium amplitude long duration pulses and low to medium temperatures, so these conditions are optimal to produce better cryomagnets.
title Mathematical analysis of a flux-jump model in superconductivity
topic Superconductivity
Pattern Formation and Solitons
url https://arxiv.org/abs/2412.14691