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Auteurs principaux: Prigozhin, Leonid, Sokolovsky, Vladimir
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2605.14818
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author Prigozhin, Leonid
Sokolovsky, Vladimir
author_facet Prigozhin, Leonid
Sokolovsky, Vladimir
contents Numerical methods for modeling thin-film magnetization are primarily focused on computing the current density distribution. The highly nonlinear current-voltage characteristic of type-II superconductors significantly complicates the accurate computation of the electric field. The T-E formulation-based mixed finite element method, previously derived for flat superconducting films, enables the simultaneous, accurate determination of both variables. Another advantage of this method is that the computational domain is limited to the film itself: no meshing of the surrounding space is required. The thin-shell approximation reduces the problem to a two-dimensional one. This work extends the T-E formulation and numerical method to non-flat superconducting shells with a metal substrate. We validate the method with several test examples, including modeling the magnetization of a sphere. The method is then applied to a realistic model of a cylindrical magnetic dynamo pump, and the generated open-circuit voltage is computed.
format Preprint
id arxiv_https___arxiv_org_abs_2605_14818
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle T-E formulation-based modeling of thin HTS shell magnetization
Prigozhin, Leonid
Sokolovsky, Vladimir
Superconductivity
Numerical Analysis
Numerical methods for modeling thin-film magnetization are primarily focused on computing the current density distribution. The highly nonlinear current-voltage characteristic of type-II superconductors significantly complicates the accurate computation of the electric field. The T-E formulation-based mixed finite element method, previously derived for flat superconducting films, enables the simultaneous, accurate determination of both variables. Another advantage of this method is that the computational domain is limited to the film itself: no meshing of the surrounding space is required. The thin-shell approximation reduces the problem to a two-dimensional one. This work extends the T-E formulation and numerical method to non-flat superconducting shells with a metal substrate. We validate the method with several test examples, including modeling the magnetization of a sphere. The method is then applied to a realistic model of a cylindrical magnetic dynamo pump, and the generated open-circuit voltage is computed.
title T-E formulation-based modeling of thin HTS shell magnetization
topic Superconductivity
Numerical Analysis
url https://arxiv.org/abs/2605.14818