Solnechno-Zemnaya Fizika

Солнечно-земная физика

2712-9640

71915

10.12737/szf-102202402

Результаты исследований

Results of current research

Результаты исследований

Turbulence development behind the bow shock during disturbed and undisturbed solar wind

Развитие турбулентности за околоземной ударной волной в периоды спокойного и возмущенного солнечного ветра

Рахманова

Людмила Сергеевна

Rakhmanova

Liudmila Sergeevna

rakhlud@gmail.com

кандидат физико-математических наук;

candidate of physical and mathematical sciences;

Хохлачев

Александр Андреевич

Khokhlachev

Aleksander Andreevich

aleks.xaa@yandex.ru

Рязанцева

Мария Олеговна

Riazantseva

Maria Olegovna

orearm@gmail.com

Ермолаев

Юрий Иванович

Yermolaev

Yuri Ivanovich

yermol@iki.rssi.ru

доктор физико-математических наук;

doctor of physical and mathematical sciences;

Застенкер

Георгий Наумович

Zastenker

Georgy Naumovich

gzastenk@iki.rssi.ru

доктор физико-математических наук;

doctor of physical and mathematical sciences;

Институт космических исследований РАН Москва Россия Space Research Institute RAS Moscow Russian Federation

Институт космических исследований РАН Москва Россия Space Research Institute of RAS (IKI) Moscow Russian Federation

Институт космических исследований РАН Москва Россия Space Research Institute RAS Moscow Russian Federation

25 06 2024

10 2 15 28 04 12 2023 21 02 2024

https://zh-szf.ru/en/nauka/article/71915/view

Магнитослой, являясь переходной областью между солнечным ветром и магнитосферой, может вносить вклад в степень геоэффективности различных крупномасштабных явлений в межпланетной среде. В настоящей работе на основе статистического анализа характеристик турбулентности плазмы в магнитоcлое на разной удаленности от головной ударной волны рассматривается динамика спектра турбулентных флуктуаций при стационарном течении солнечного ветра и при взаимодействии с магнитосферой коронального выброса массы и области коротирующего взаимодействия. Показано, что при пересечении головной ударной волны для всех типов солнечного ветра происходит изменение свойств спектров и при дальнейшем распространении плазмы к флангам магнитослоя характеристики турбулентности, как правило, восстанавливаются. Однако в периоды корональных выбросов массы в развитии турбулентного каскада наблюдаются особенности. Кроме того, для событий, относящихся к возмущенному солнечному ветру, имеется связь между характеристиками турбулентности на субионных масштабах и параметрами окружающей космической среды, такими как плазменный параметр β, угол θBN между нормалью к ударной волне и вектором межпланетного магнитного поля, скорость плазмы солнечного ветра, а также расстояние до границ магнитослоя.

Magnetosheath is a transition layer between the solar wind and the magnetosphere and may contribute to the geoeffectiveness of various large-scale interplanetary phenomena. In this paper, we examine the dynamics of the turbulent fluctuation spectra behind the bow shock during undisturbed solar wind and when interplanetary coronal mass ejections and corotation interaction regions interact with the magnetosphere. The study is based on statistical analysis of the turbulence features inside the magnetosheath at different distances from the bow shock. We demonstrate that the turbulence features change when plasma crosses the bow shock for the solar wind of all types and they usually recover when plasma moves away from the bow shock. However, peculiarities in the turbulence development occur during interplanetary coronal mass ejections. Moreover, during disturbed solar wind there are relations between the turbulence features at the sub-ion scales and background plasma parameters such as plasma parameter β, the angle θBN between the interplanetary magnetic field and the local bow shock normal, solar wind bulk velocity, and the distance to the magnetosheath boundaries.

солнечный ветер магнитослой турбулентность космическая плазма

solar wind magnetosheath turbulence space plasma

Исследование выполнено за счет гранта Российского научного фонда № 22-72-00105, [https://rscf.ru/project/22-72-00105/]

The work was financially supported by the Russian Science Foundation (Grant No. 22-72-00105) [https://rscf.ru/project/22-72-00105/]

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