Your search keyword '"Dubyagin, S. (Stepan)"' showing total 2 results

1. Outer Van Allen belt trapped and precipitating electron flux responses to two interplanetary magnetic clouds of opposite polarity

Author

George, H. (Harriet), Kilpua, E. (Emilia), Osmane, A. (Adnane), Asikainen, T. (Timo), Kalliokoski, M. M. (Milla M. H.), Rodger, C. J. (Craig J.), Dubyagin, S. (Stepan), Palmroth, M. (Minna), George, H. (Harriet), Kilpua, E. (Emilia), Osmane, A. (Adnane), Asikainen, T. (Timo), Kalliokoski, M. M. (Milla M. H.), Rodger, C. J. (Craig J.), Dubyagin, S. (Stepan), and Palmroth, M. (Minna)

Abstract

Recently, it has been established that interplanetary coronal mass ejections (ICMEs) can dramatically affect both trapped electron fluxes in the outer radiation belt and precipitating electron fluxes lost from the belt into the atmosphere. Precipitating electron fluxes and energies can vary over a range of timescales during these events. These variations depend on the initial energy and location of the electron population and the ICME characteristics and structures. One important factor controlling electron dynamics is the magnetic field orientation within the ejecta that is an integral part of the ICME. In this study, we examine Van Allen Probes (RBSPs) and Polar Orbiting Environmental Satellites (POESs) data to explore trapped and precipitating electron fluxes during two ICMEs. The ejecta in the selected ICMEs have magnetic cloud characteristics that exhibit the opposite sense of the rotation of the north–south magnetic field component (BZ). RBSP data are used to study trapped electron fluxes in situ, while POES data are used for electron fluxes precipitating into the upper atmosphere. The trapped and precipitating electron fluxes are qualitatively analysed to understand their variation in relation to each other and to the magnetic cloud rotation during these events. Inner magnetospheric wave activity was also estimated using RBSP and Geostationary Operational Environmental Satellite (GOES) data. In each event, the largest changes in the location and magnitude of both the trapped and precipitating electron fluxes occurred during the southward portion of the magnetic cloud. Significant changes also occurred during the end of the sheath and at the sheath–ejecta boundary for the cloud with south to north magnetic field rotation, while the ICME with north to south rotation had significant changes at the end boundary of the cloud. The sense of rotation of BZ and its profile also clearly affects the coherence of the trapped and/or precipitating flux changes, ti

Published

2020

2. Cosmic noise absorption signature of particle precipitation during interplanetary coronal mass ejection sheaths and ejecta

Author

Kilpua, E. (Emilia), Juusola, L. (Liisa), Grandin, M. (Maxime), Kero, A. (Antti), Dubyagin, S. (Stepan), Partamies, N. (Noora), Osmane, A. (Adnane), George, H. (Harriet), Kalliokoski, M. (Milla), Raita, T. (Tero), Asikainen, T. (Timo), Palmroth, M. (Minna), Kilpua, E. (Emilia), Juusola, L. (Liisa), Grandin, M. (Maxime), Kero, A. (Antti), Dubyagin, S. (Stepan), Partamies, N. (Noora), Osmane, A. (Adnane), George, H. (Harriet), Kalliokoski, M. (Milla), Raita, T. (Tero), Asikainen, T. (Timo), and Palmroth, M. (Minna)

Abstract

We study here energetic-electron (E>30 keV) precipitation using cosmic noise absorption (CNA) during the sheath and ejecta structures of 61 interplanetary coronal mass ejections (ICMEs) observed in the near-Earth solar wind between 1997 and 2012. The data come from the Finnish riometer (relative ionospheric opacity meter) chain from stations extending from auroral (IVA, 65.2∘ N geomagnetic latitude; MLAT) to subauroral (JYV, 59.0∘ N MLAT) latitudes. We find that sheaths and ejecta lead frequently to enhanced CNA (>0.5 dB) both at auroral and subauroral latitudes, although the CNA magnitudes stay relatively low (medians around 1 dB). Due to their longer duration, ejecta typically lead to more sustained enhanced CNA periods (on average 6–7 h), but the sheaths and ejecta were found to be equally effective in inducing enhanced CNA when relative-occurrence frequency and CNA magnitude were considered. Only at the lowest-MLAT station, JYV, ejecta were more effective in causing enhanced CNA. Some clear trends of magnetic local time (MLT) and differences between the ejecta and sheaths were found. The occurrence frequency and magnitude of CNA activity was lowest close to midnight, while it peaked for the sheaths in the morning and afternoon/evening sectors and for the ejecta in the morning and noon sectors. These differences may reflect differences in typical MLT distributions of wave modes that precipitate substorm-injected and trapped radiation belt electrons during the sheaths and ejecta. Our study also emphasizes the importance of substorms and magnetospheric ultra-low-frequency (ULF) waves for enhanced CNA.

Published

2020