Add to ORKGSuperposed epoch analyses were performed on 193 significant relativistic electron flux dropout events, in order to study the roles of different solar wind parameters in driving the depletion of relativistic electrons, using '16 years of data from the POES and GOES missions, and the OMNIWEB solar wind database. We find that the solar wind dynamic pressure and interplanetary magnetic field (IMF) Bz play key roles in causing the relativistic electron flux dropouts, but also that either large solar wind dynamic pressure or strong southward IMF Bz by itself is capable of producing the significant depletion of relativistic electrons. The relativistic electron flux dropouts occur not only when the magnetopause is compressed closer to the Earth but...
Magnetopause shadowing and wave-particle interactions are recognized as the two primary mechanisms f...
It has been suggested that drift loss to the magnetopause can be one of the major loss mechanisms co...
Relativistic electrons in the magnetosphere are both energized and lost via their interaction with p...
In this study, we apply superposed epoch analysis to the 1.5-6.0 MeV electron flux dropout events ob...
During 124 high-speed-stream-driven storms from two solar cycles, a multispacecraft average of the 1...
Radiation belt electron flux dropouts are a kind of drastic variation in the Earth's magnetosphere,...
We have investigated characteristic solar wind dynamics associated with relativistic electron events...
Geomagnetic storms can either increase or decrease relativistic electron fluxes in the outer radiati...
Energetic electrons are trapped in the Earth’s radiation belts which occupy a toroidal region betwee...
The radiation belts are highly dynamic regions of relativistic particles trapped in the Earth’s magn...
A new scenario is presented for the cause of magnetospheric relativistic electron decreases (REDs) a...
The Earth's electron outer radiation belt is a highly variable region in which the populations can v...
Energetic radiation belt electron fluxes can undergo sudden dropouts in response to different solar...
Electron precipitation from the Earth's inner magnetosphere transmits solar variability to the Earth...
Understanding how the relativistic electron fluxes drop out in the outer radiation belt under differ...
Magnetopause shadowing and wave-particle interactions are recognized as the two primary mechanisms f...
It has been suggested that drift loss to the magnetopause can be one of the major loss mechanisms co...
Relativistic electrons in the magnetosphere are both energized and lost via their interaction with p...
In this study, we apply superposed epoch analysis to the 1.5-6.0 MeV electron flux dropout events ob...
During 124 high-speed-stream-driven storms from two solar cycles, a multispacecraft average of the 1...
Radiation belt electron flux dropouts are a kind of drastic variation in the Earth's magnetosphere,...
We have investigated characteristic solar wind dynamics associated with relativistic electron events...
Geomagnetic storms can either increase or decrease relativistic electron fluxes in the outer radiati...
Energetic electrons are trapped in the Earth’s radiation belts which occupy a toroidal region betwee...
The radiation belts are highly dynamic regions of relativistic particles trapped in the Earth’s magn...
A new scenario is presented for the cause of magnetospheric relativistic electron decreases (REDs) a...
The Earth's electron outer radiation belt is a highly variable region in which the populations can v...
Energetic radiation belt electron fluxes can undergo sudden dropouts in response to different solar...
Electron precipitation from the Earth's inner magnetosphere transmits solar variability to the Earth...
Understanding how the relativistic electron fluxes drop out in the outer radiation belt under differ...
Magnetopause shadowing and wave-particle interactions are recognized as the two primary mechanisms f...
It has been suggested that drift loss to the magnetopause can be one of the major loss mechanisms co...
Relativistic electrons in the magnetosphere are both energized and lost via their interaction with p...