Suppression of the dayside magnetopause surface modes

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...

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Published in:Solar-Terrestrial Physics
Main Authors: Pilipenko V.A., Kozyreva O.V., Baddeley L., Lorentzen D.A., Belakhovsky V.B.
Format: Article in Journal/Newspaper
Language:English
Published: INFRA-M 2017
Subjects:
ULF waves
magnetopause
open-closed boundary
MHD surface modes
Alfven resonator
Astrophysics
QB460-466
Svalbard
Online Access:https://doi.org/10.12737/stp-34201702
https://doaj.org/article/22b123a1a905402da7d6dd9603aa58f7
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spelling ftdoajarticles:oai:doaj.org/article:22b123a1a905402da7d6dd9603aa58f7 2023-05-15T18:29:53+02:00 Suppression of the dayside magnetopause surface modes Pilipenko V.A. Kozyreva O.V. Baddeley L. Lorentzen D.A. Belakhovsky V.B. 2017-12-01T00:00:00Z https://doi.org/10.12737/stp-34201702 https://doaj.org/article/22b123a1a905402da7d6dd9603aa58f7 EN eng INFRA-M https://naukaru.ru/ru/nauka/article/19707/view https://doaj.org/toc/2500-0535 doi:10.12737/stp-34201702 2500-0535 https://doaj.org/article/22b123a1a905402da7d6dd9603aa58f7 Solar-Terrestrial Physics, Vol 3, Iss 4, Pp 17-25 (2017) ULF waves magnetopause open-closed boundary MHD surface modes Alfven resonator Astrophysics QB460-466 article 2017 ftdoajarticles https://doi.org/10.12737/stp-34201702 2022-12-31T02:39:28Z 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. Article in Journal/Newspaper Svalbard Directory of Open Access Journals: DOAJ Articles Svalbard Solar-Terrestrial Physics 17 25
institution Open Polar
collection Directory of Open Access Journals: DOAJ Articles
op_collection_id ftdoajarticles
language English
topic ULF waves
magnetopause
open-closed boundary
MHD surface modes
Alfven resonator
Astrophysics
QB460-466
spellingShingle ULF waves
magnetopause
open-closed boundary
MHD surface modes
Alfven resonator
Astrophysics
QB460-466
Pilipenko V.A.
Kozyreva O.V.
Baddeley L.
Lorentzen D.A.
Belakhovsky V.B.
Suppression of the dayside magnetopause surface modes
topic_facet ULF waves
magnetopause
open-closed boundary
MHD surface modes
Alfven resonator
Astrophysics
QB460-466
description 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.
format Article in Journal/Newspaper
author Pilipenko V.A.
Kozyreva O.V.
Baddeley L.
Lorentzen D.A.
Belakhovsky V.B.
author_facet Pilipenko V.A.
Kozyreva O.V.
Baddeley L.
Lorentzen D.A.
Belakhovsky V.B.
author_sort Pilipenko V.A.
title Suppression of the dayside magnetopause surface modes
title_short Suppression of the dayside magnetopause surface modes
title_full Suppression of the dayside magnetopause surface modes
title_fullStr Suppression of the dayside magnetopause surface modes
title_full_unstemmed Suppression of the dayside magnetopause surface modes
title_sort suppression of the dayside magnetopause surface modes
publisher INFRA-M
publishDate 2017
url https://doi.org/10.12737/stp-34201702
https://doaj.org/article/22b123a1a905402da7d6dd9603aa58f7
geographic Svalbard
geographic_facet Svalbard
genre Svalbard
genre_facet Svalbard
op_source Solar-Terrestrial Physics, Vol 3, Iss 4, Pp 17-25 (2017)
op_relation https://naukaru.ru/ru/nauka/article/19707/view
https://doaj.org/toc/2500-0535
doi:10.12737/stp-34201702
2500-0535
https://doaj.org/article/22b123a1a905402da7d6dd9603aa58f7
op_doi https://doi.org/10.12737/stp-34201702
container_title Solar-Terrestrial Physics
container_start_page 17
op_container_end_page 25
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