Magnetospheric response to the interaction with the sporadic solar wind diamagnetic structure-Reference-Cited by-同舟云学术

Magnetospheric response to the interaction with the sporadic solar wind diamagnetic structure

Published:2021-09-28 Issue: Volume: Page:12-30
ISSN:2712-9640
Container-title:Solnechno-Zemnaya Fizika
language:en
Short-container-title:

Author:

Parkhomov Vladimir¹,Eselevich Viktor²,Eselevich Maxim²,Dmitriev Alexei³⁴,Suvorova Alla⁵,Khomutov Sergey⁶,Tsegmed Battuulai⁷,Tero Raita⁸

Affiliation:

1. Baikal State University

2. Institute of Solar Terrestrial Physics SB RAS

3. Skobeltsyn Institute of Nuclear Physics, Moscow State University, Moscow , Russian Federation

4. Department of Space Science and Engineering, National Central University, Taiwan

5. Skobeltsyn Institute of Nuclear Physics, Moscow State University

6. Institute of Cosmophysical Research and Radio Wave Propagation FEB RAS

7. Institute of Astronomy and Geophysics AS Mongolia

8. Sodankylä Geophysical Observatory

Abstract

We report the results of a study on the movement of the solar wind diamagnetic structure (DS), which is a sequence of smaller-scale microDS being part of the May 18, 2013 coronal mass ejection, from a source on the Sun to Earth’s surface. DS determined from the high negative correlation coefficient (r=–0.9) between the IMF modulus (B) and the SW density (N) on the ACE and Wind satellites at the L1 point, on the THB and THC satellites (r=–0.9) in near-Earth orbit, and on the THA satellite inside the magnetosphere is carried by the solar wind from the Sun to Earth’s orbit, while maintaining its fine internal structure. Having a large size in the radial direction (≈763 Rᴇ, where Rᴇ is the Earth radius), DS flows around the magnetosphere. At the same time, microDS of size ≤13 Rᴇ passes through the bow shock and magnetopause as a magnetized plasmoid in which the ion concentration increases from 10 cm⁻³ to 90 cm⁻³, and the velocity decreases as it moves toward the magnetotail. When a microDS passes through the magnetopause, a pulsed electric field of ~400 mV/m is generated with subsequent oscillations with a period of T~200 s and an amplitude of ~50 mV/m. The electric field accelerates charged particles of the radiation belt and produces modulated fluxes of protons in an energy range 95–575 keV on the day side and electrons in 40–475 keV and protons in 95–575 keV on the night side. In the duskside magnetosphere (19–23 MLT), the substorm activation is observed in geomagnetic pulsations and auroras, but without a magnetic negative bay. In the post-midnight sector (01–05 MLT), a sawtooth substorm occurs without the growth phase and breakup with deep modulation of the ionospheric current and auroral absorption. The duration of all phenomena in the magnetosphere and on Earth is determined by the period of interaction between DS and the magnetosphere (~4 hrs). To interpret the regularities of the magnetospheric response to the interaction with DS, we consider alternative models of the impulsive passage of DS from SW to the magnetosphere and the classical model of reconnection of IMF and the geomagnetic field.

Publisher

Infra-M Academic Publishing House

Reference44 articles.

1. Гульельми А.В. МГД-волны в околоземной плазме. М.: Наука, 1979. С. 70., 1. Akasofu S.-I. Auroral substorms: search for processes causing the expansion phase in terms of the electric current approach. Space Sci Rev. 2017, vol. 212, pp. 341–381. DOI: 10.1007/s11214-017-0363-7.

2. Ермолаев Ю.И., Николаева Н.С., Лодкина И.Г., Ермолаев М.Ю. Каталог крупномасштабных явлений солнечного ветра для периода 1976–2000 гг. Космические исследования. 2009. Т. 47, № 2. C. 99–113., Belakhovsky V., Pilipenko V., Engebretson M., Sakharov Y., Selivanov V. Impulsive disturbances of the geomagnetic field as a cause of induced currents of electric power lines. Journal of Space Weather and Space Climate. 2019, vol. 9, no. A18, pp. 2–19. DOI: 10.1051/swsc/2019015.

3. Еселевич М.В., Еселевич В.Г. Cпорадические потоки плазмы и их источники в период чрезвычайной активности Солнца с 26 октября по 6 ноября 2003 г. Космические исследования. 2004. Т. 42, № 6. C. 595–607., Dmitriev A.V., Suvorova A.V. Large-scale jets in the magnetosheath and plasma penetration across the magnetopause: THEMIS observations. J. Geophys. Res.: Space Phys. 2015, vol. 120, iss. 6. DOI: 10.1002/2014JA020953.

4. Еселевич М.В., Еселевич В.Г. Фрактальная структура гелиосферного плазменного слоя на орбите Земли. Геомагнетизм и аэрономия. 2005. Т. 45, № 3. C. 347–358., Echim M.M., Lemaire J.F. Laboratory and numerical simulations of the impulsive penetration mechanism. Space Sci. Rev. 2000, vol. 92, pp. 565–601.

5. Мишин В.В. О потоке волновой энергии в магнитосферу под действием пульсаций давления солнечного ветра. Исслед. по геомагнетизму, аэрономии и физике Солнца. Новосибирск: Наука, 1996. Вып. 104. C. 182–185., Ermolaev Yu.I., Nikolaeva N.S., Lodkina I.G., Ermolaev M.Yu. Catalog of large-scale solar wind phenomena during 1976–2000. Cosmic Res. 2009, vol. 47, no. 2, pp. 81–94. DOI: 10.1134/S0010952509020014.

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