Solar-Terrestrial Physics

Солнечно-земная физика / Solnechno-Zemnaya Fizika / Solar-Terrestrial Physics

2712-9640

16981

10.12737/szf-34201702

Результаты исследований

Results of current research

Результаты исследований

Suppression of the dayside magnetopause surface modes

Подавление поверхностных мод на дневной магнитопаузе

https://orcid.org/0000-0003-3056-7465

Пилипенко

Вячеслав Анатольевич

Pilipenko

Vyacheslav Anatolievich

space.soliton@gmail.com

доктор физико-математических наук;

doctor of physical and mathematical sciences;

https://orcid.org/0000-0003-0825-151X

Козырева

Ольга Васильевна

Kozyreva

Olga Vasilyevna

kozyreva@ifz.ru

доктор физико-математических наук;

doctor of physical and mathematical sciences;

Бэддели

Лиза

Baddeley

Liza

lisa.baddeley@unis.no

Лорентцен

Дэг

Lorentzen

Dag

dag.lorentzen@unis.no

Белаховский

Владимир Борисович

Belahovskiy

Vladimir Borisovich

belakhov@mail.ru

кандидат физико-математических наук;

candidate of physical and mathematical sciences;

Институт физики Земли им. О.Ю. Шмидта РАН Москва Россия Schmidt Institute of Physics of the Earth RAS Moscow Russian Federation

Геофизический центр РАН Москва Россия Geophysical Center RAS Moscow Russian Federation

Институт космических исследований Москва Россия Space Research Institute Moscow Russian Federation

Институт физики Земли им. О.Ю. Шмидта РАН Москва Россия Schmidt Institute of Physics of the Earth, RAS Moscow Russian Federation

Университетский Центр в Свалбарде, Свалбард Норвегия University Centre in Svalbard Svalbard Norway

Центр космической науки в Биркеланне Биркеланн Норвегия Birkeland Center for Space Science Birkeland Norway

Университетский Центр в Свалбарде, Свалбард Норвегия University Centre in Svalbard Svalbard Norway

Центр космической науки в Биркеланне Биркеланн Норвегия Birkeland Center for Space Science Birkeland Norway

Полярный геофизический институт Апатиты Россия Polar Geophysical Institute Apatity Russian Federation

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https://zh-szf.ru/en/nauka/article/16981/view

В геофизической литературе активно обсуждается гипотеза о том, что поверхностные волны на магнитопаузе могли бы быть источником дневных широкополосных пульсаций диапазона Pc5–6 (~1–2 мГц) на околокасповых широтах. Однако первые попытки найти наземный отклик на эти колебания не дали обнадеживающих результатов. Так, сопоставление дневной границы открытых и замкнутых силовых линий (т. н. OCB — Open-Closed field line Boundary) по данным радара SuperDARN с пространственной структурой Pc5–6 пульсаций, зарегистрированных на сети магнитометров на околокасповых широтах, показало, что спектральная мощность этих пульсаций имеет максимум преимущественно на 2–3° более внутренних оболочках магнитосферы, чем положение OCB. Дополнительно связь между OCB и геомагнитными пульсациями исследована путем сопоставления профиля мощности дневных пульсаций с экваториальной границей аврорального овала, определяемой по красной кислородной эмиссии по данным сканирующего фотометра на Свалбарде. В большинстве проанализированных событий «эпицентр» мощности Pc5–6 пульсаций оказался примерно на 1–2° более низкой широте, чем OCB, определенной по оптическим данным. Таким образом, дневные пульсации диапазона Pc5–6 нельзя напрямую связывать с поверхностными модами на магнитопаузе или колебаниями последней замкнутой силовой линии. Отсутствие наземного отклика на эти моды в области ионосферной проекции OCB кажется удивительным. В качестве возможного объяснения мы предположили, что сильная вариабельность внешней магнитосферы вблизи магнитопаузы может подавлять возбуждение колебаний в этой области. Для количественной проверки этой гипотезы, нами рассмотрено возбуждение внешним источником МГД-резонатора между сопря-женными ионосферами со стохастическими флуктуациями собственной частоты. Решение этой задачи действительно показывает существенное ухудшение резонансных свойств МГД-резонатора даже при сравнительно низком уровне фоновых флуктуаций. Этот эффект в принципе может объяснить, почему наземный отклик на магнитосферные колебания отсутствует в области проекции OCB, но наблюдается на более внутренних магнитных оболочках, где структура магнитного поля и плазмы более стабильна.

Magnetopause surface eigenmodes were suggested as a potential source of dayside high-latitude broadband pulsations in the Pc5-6 band (frequency about 1–2 mHz). However, the search for a ground signature of these modes has not provided encouraging results. The comparison of multi-instrument data from Svalbard with the latitudinal structure of Pc5-6 pulsations, recorded by magnetometers covering near-cusp latitudes, has shown that often the latitudinal maximum of pulsation power occurs about 2–3° deeper in the magnetosphere than the dayside open-closed field line boundary (OCB). The OCB proxy was determined from SuperDARN radar data as the equatorward boundary of enhanced width of a return radio signal. The OCB-ULF correspondence is further examined by comparing the latitudinal profile of the near-noon pulsation power with the equatorward edge of the auroral red emission from the meridian scanning photometer. In most analyzed events, the “epicenter” of Pc5-6 power is at 1–2° lower latitude than the optical OCB proxy. Therefore, the dayside Pc5-6 pulsations cannot be associated with the ground image of the magnetopause surface modes or with oscillations of the last field line. A lack of ground response to these modes beneath the ionospheric projection of OCB seems puzzling. As a possible explanation, we suggest that a high variability of the outer magnetosphere near the magnetopause region may suppress the excitation efficiency. To quantify this hypothesis, we consider a driven field line resonator terminated by conjugate ionospheres with stochastic fluctuations of its eigenfrequency. A solution of this problem predicts a substantial deterioration of resonant properties of MHD resonator even under a relatively low level of background fluctuations. This effect may explain why there is no ground response to magnetopause surface modes or oscillations of the last field line at the OCB latitude, but it can be seen at somewhat lower latitudes with more regular and stable magnetic and plasma structure.

УНЧ-волны магнитопауза граница замкнутых и разомкнутых силовых линий поверхностные МГД-моды альвеновский резонатор

ULF waves magnetopause open-closed boundary MHD surface modes Alfven resonator

IONOSPHERIC FOOTPRINT OF THE DAYSIDE OCB FROM OPTICAL AND HF RADAR OBSERVATIONSThe open-closed field line boundary (OCB) is the boundary that separates magnetospheric field lines that are dragged by the interplanetary magnetic field from those that are closed within the magnetosphere. The ability to monitor the OCB location allows us to study the electrodynamics of magnetosphere–ionosphere coupling, in particular to estimate energy storage and release in the magnetosphere. There are several methods for discriminating the ionospheric footprint of the dayside OCB, but each of them has some merits and drawbacks.The open/closed separatrix can be identified using particle precipitation boundaries observed by low-altitude spacecraft [Newell, Meng, 1988; Oksavik et al., 2000]. The poleward edge of high-energy (>10 keV) electron precipitation (‘‘trapping boundary’’) corresponds to particles trapped on closed field lines. Field lines poleward of this region must therefore be open. However, the measurements can be made with cadence about 90 min and along orbit only.Precipitating soft electrons produce plasma irregularities, and strong coherent backscatter from these irregularities can be monitored by Super Dual Auroral Radar Network (SuperDARN) radars. The spectral width of the Doppler velocity of measured backscattered signal can be interpreted as a manifestation of plasma turbulence of the scattering region. The transition from narrow to broad spectral widths has been utilized to investigate the location of ionospheric boundaries [Baker et al., 1995]. Many studies have revealed that the high-latitude broad Doppler spectral width can be used as an indicator for the cusp region [Moen et al., 2001], even though the interpretation of the broad spectral width is still elusive. However, ionospheric regions with elevated turbulence level can be associated not only with the cusp proper, but with the low-latitude boundary layer; hence, this method may provide ambiguous results.A demarcation of the cusp soft electron precipitation can be determined by comparing the equatorward boundary of the red (630.0 nm) auroral emission along the photometer meridian scanning [Lorentzen et al., 1996]. Precipitation of soft electrons with 0.1–1 keV energies is a good indicator of open magnetic field lines and corresponds to the cusp aurora dominated by the red emission (Rayleigh intensity ratio 630.0/557.7>1) [Lorentzen, Moen, 2000; Johnsen, Lorentzen, 2012]. However, dayside auroral optical measurements can be made during winter months only.The co-location of the equatorward edge of the HF radar cusp and the cusp auroral emission has been extensively studied [Yeoman et al., 1997]. Rodger et al. [1995] showed that the radar cusp signatures were located ~0.5° equatorward of the optical cusp, whereas Milan et al. [1999] found that the equatorward boundaries of the optical cusp were, on average, located at slightly lower latitudes than the radar cusp. Comparing the spectral width method to the optical method, the radar OCB proxy was seen to be on average 0.5–1.6° (56–170 km) poleward of the optical OCB [Chen et al., 2015].A new discriminator of OCB was suggested on the basis of ground magnetometer observations of high-latitude ultra-low-frequency (ULF) activity. The background of this tool is described in the following section.

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