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Main Authors: Illarionov, E., Stepanov, R., Kuzanyan, K. M., Kisielius, V.
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.10548
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author Illarionov, E.
Stepanov, R.
Kuzanyan, K. M.
Kisielius, V.
author_facet Illarionov, E.
Stepanov, R.
Kuzanyan, K. M.
Kisielius, V.
contents Physical models aimed to reproduce basic features of the solar sunspot cycle are typically based on the solar dynamo mechanism. Usually qualitative arguments are used to define parameters of the model, among which a challenging component is the nonlinear form of quenching of the alpha-effect governing regeneration of the magnetic field. We propose a novel approach, in which the functional form of the alpha-quenching is represented by a neural network model embedded into neural differential dynamo equations trained on observational data. For demonstration, we consider a low-mode dynamo model and find a wide set of alpha-quenching functions and corresponding dynamo numbers that provide an accurate fit to the average profile of the solar cycle data given by sunspot numbers. Within this set, we observe a strong relationship between the dynamo number and the shape of the alpha-quenching function indicating that additional magnetic field data or constraints are essential to unambiguously infer parameters of the dynamo model. In our opinion, the neural differential approach opens a new prospect for data-driven investigation of the closure problem in dynamo theory.
format Preprint
id arxiv_https___arxiv_org_abs_2603_10548
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Neural Differential Equations for the Solar Dynamo
Illarionov, E.
Stepanov, R.
Kuzanyan, K. M.
Kisielius, V.
Solar and Stellar Astrophysics
Plasma Physics
Physical models aimed to reproduce basic features of the solar sunspot cycle are typically based on the solar dynamo mechanism. Usually qualitative arguments are used to define parameters of the model, among which a challenging component is the nonlinear form of quenching of the alpha-effect governing regeneration of the magnetic field. We propose a novel approach, in which the functional form of the alpha-quenching is represented by a neural network model embedded into neural differential dynamo equations trained on observational data. For demonstration, we consider a low-mode dynamo model and find a wide set of alpha-quenching functions and corresponding dynamo numbers that provide an accurate fit to the average profile of the solar cycle data given by sunspot numbers. Within this set, we observe a strong relationship between the dynamo number and the shape of the alpha-quenching function indicating that additional magnetic field data or constraints are essential to unambiguously infer parameters of the dynamo model. In our opinion, the neural differential approach opens a new prospect for data-driven investigation of the closure problem in dynamo theory.
title Neural Differential Equations for the Solar Dynamo
topic Solar and Stellar Astrophysics
Plasma Physics
url https://arxiv.org/abs/2603.10548