Standard

Magnetic fields and electric currents around the dayside magnetopause as inferred from data-constrained modeling. / Tsyganenko, Nikolai; Semenov, Vladimir ; Erkaev, Nikolay; Gubaidulin, Nikita.

In: Frontiers in Astronomy and Space Sciences, Vol. 11, 18.07.2024, p. 1-15.

Research output: Contribution to journalArticlepeer-review

Harvard

APA

Vancouver

Author

BibTeX

@article{9598e097adaf46d6b6ea63193d8aab27,
title = "Magnetic fields and electric currents around the dayside magnetopause as inferred from data-constrained modeling",
abstract = "Based on a new mathematical framework and large multi-year multi-missiondata sets, we reconstruct electric currents and magnetic fields around the dayside magnetopause and their dependence on the incoming solar wind, IMF, and geodipole tilt. The model architecture builds on previously developed mathematical frameworks and includes two separate blocks: for the magnetosheath and for the adjacent outer magnetosphere. Accordingly, the model is developed in two stages: 1) reconstruction of a best-fit magnetopause and underlying dayside magnetosphere, based on a simple shielded configuration, and 2) derivation of the magnetosheath magnetic field, represented by a sum of toroidal and poloidal terms, each expanded into spherical harmonic series of angular coordinates and powers of normal distance from the boundary. The spacecraft database covers the period from 1995 through 2022 and is composed of data from Geotail, Cluster, Themis, and MMS, with the total number of 1-min averages about 3 M. The modeling reveals orderly patterns of the IMF draping around the magnetosphere and of the magnetopause currents, controlled by the IMF orientation, solar wind pressure, and the Earth{\textquoteright}s dipole tilt. The obtained results are discussed in terms of the magnetosheath flux pile-up and the dayside magnetosphere erosion during periods of northward or southward IMF, respectively.",
keywords = "магнитосфера, солнечный ветер, геомагнитное поле, магнитопауза, магнитослой, моделирование, спутниковые измерения, magnetosphere, magnetosheath,, magnetopause, modeling, solar wind, IMF",
author = "Nikolai Tsyganenko and Vladimir Semenov and Nikolay Erkaev and Nikita Gubaidulin",
year = "2024",
month = jul,
day = "18",
doi = "10.3389/fspas.2024.1425165",
language = "English",
volume = "11",
pages = "1--15",
journal = "Frontiers in Astronomy and Space Sciences",
issn = "2296-987X",
publisher = "Frontiers Media S.A.",

}

RIS

TY - JOUR

T1 - Magnetic fields and electric currents around the dayside magnetopause as inferred from data-constrained modeling

AU - Tsyganenko, Nikolai

AU - Semenov, Vladimir

AU - Erkaev, Nikolay

AU - Gubaidulin, Nikita

PY - 2024/7/18

Y1 - 2024/7/18

N2 - Based on a new mathematical framework and large multi-year multi-missiondata sets, we reconstruct electric currents and magnetic fields around the dayside magnetopause and their dependence on the incoming solar wind, IMF, and geodipole tilt. The model architecture builds on previously developed mathematical frameworks and includes two separate blocks: for the magnetosheath and for the adjacent outer magnetosphere. Accordingly, the model is developed in two stages: 1) reconstruction of a best-fit magnetopause and underlying dayside magnetosphere, based on a simple shielded configuration, and 2) derivation of the magnetosheath magnetic field, represented by a sum of toroidal and poloidal terms, each expanded into spherical harmonic series of angular coordinates and powers of normal distance from the boundary. The spacecraft database covers the period from 1995 through 2022 and is composed of data from Geotail, Cluster, Themis, and MMS, with the total number of 1-min averages about 3 M. The modeling reveals orderly patterns of the IMF draping around the magnetosphere and of the magnetopause currents, controlled by the IMF orientation, solar wind pressure, and the Earth’s dipole tilt. The obtained results are discussed in terms of the magnetosheath flux pile-up and the dayside magnetosphere erosion during periods of northward or southward IMF, respectively.

AB - Based on a new mathematical framework and large multi-year multi-missiondata sets, we reconstruct electric currents and magnetic fields around the dayside magnetopause and their dependence on the incoming solar wind, IMF, and geodipole tilt. The model architecture builds on previously developed mathematical frameworks and includes two separate blocks: for the magnetosheath and for the adjacent outer magnetosphere. Accordingly, the model is developed in two stages: 1) reconstruction of a best-fit magnetopause and underlying dayside magnetosphere, based on a simple shielded configuration, and 2) derivation of the magnetosheath magnetic field, represented by a sum of toroidal and poloidal terms, each expanded into spherical harmonic series of angular coordinates and powers of normal distance from the boundary. The spacecraft database covers the period from 1995 through 2022 and is composed of data from Geotail, Cluster, Themis, and MMS, with the total number of 1-min averages about 3 M. The modeling reveals orderly patterns of the IMF draping around the magnetosphere and of the magnetopause currents, controlled by the IMF orientation, solar wind pressure, and the Earth’s dipole tilt. The obtained results are discussed in terms of the magnetosheath flux pile-up and the dayside magnetosphere erosion during periods of northward or southward IMF, respectively.

KW - магнитосфера, солнечный ветер, геомагнитное поле

KW - магнитопауза, магнитослой, моделирование, спутниковые измерения

KW - magnetosphere, magnetosheath,

KW - magnetopause, modeling, solar wind, IMF

UR - https://www.mendeley.com/catalogue/d3fa3966-e892-348b-a614-fbc83c9c6ce6/

U2 - 10.3389/fspas.2024.1425165

DO - 10.3389/fspas.2024.1425165

M3 - Article

VL - 11

SP - 1

EP - 15

JO - Frontiers in Astronomy and Space Sciences

JF - Frontiers in Astronomy and Space Sciences

SN - 2296-987X

ER -

ID: 121844417