Add to ORKGA flux dropout is a sudden and sizable decrease in the energetic electron population of the outer radiation belt on the time scale of a few hours. We simulated a flux dropout of highly relativistic 2.5 MeV electrons using the Radiation Belt Environment model, incorporating the pitch angle diffusion coefficients caused by electromagnetic ion cyclotron (EMIC) waves for the geomagnetic storm events of 23-26 October 2002. This simulation showed a remarkable decrease in the 2.5 MeV electron flux during main phase of the storm, compared to those without EMIC waves. This decrease was independent of magnetopause shadowing or drift loss to the magnetopause. We suggest that the flux decrease was likely to be primarily due to pitch angle scattering to...
Main phase flux dropouts often promote depletion of the outer electron radiation belt. The quantific...
Relativistic (>1 MeV) electron flux increases in the Earth's radiation belts are significantly under...
Outer zone radiation belt electrons can undergo gyroresonant interaction with various magnetospheric...
Geomagnetic storms can either increase or decrease relativistic electron fluxes in the outer radiati...
In this study we investigate two distinct loss mechanisms responsible for the rapid dropouts of radi...
The dynamic variability of Earth's outer radiation belt is due to the competition among various part...
The radiation belts are highly dynamic regions of relativistic particles trapped in the Earth’s magn...
Magnetopause shadowing and wave-particle interactions are recognized as the two primary mechanisms f...
Energetic electrons are trapped in the Earth’s radiation belts which occupy a toroidal region betwee...
Electromagnetic Ion Cyclotron (EMIC) waves cause electron loss in the radiation belts by resonating ...
Abstract There has been increasing evidence for pitch angle scattering of relativistic electrons by...
Electromagnetic ion cyclotron (EMIC) waves which propagate at frequencies below the proton gyrofrequ...
Electromagnetic ion cyclotron (EMIC) waves which propagate at frequencies below the proton gyrofrequ...
The observations suggest that the dropout may have been caused by two separate mechanisms that opera...
In this study, we apply superposed epoch analysis to the 1.5-6.0 MeV electron flux dropout events ob...
Main phase flux dropouts often promote depletion of the outer electron radiation belt. The quantific...
Relativistic (>1 MeV) electron flux increases in the Earth's radiation belts are significantly under...
Outer zone radiation belt electrons can undergo gyroresonant interaction with various magnetospheric...
Geomagnetic storms can either increase or decrease relativistic electron fluxes in the outer radiati...
In this study we investigate two distinct loss mechanisms responsible for the rapid dropouts of radi...
The dynamic variability of Earth's outer radiation belt is due to the competition among various part...
The radiation belts are highly dynamic regions of relativistic particles trapped in the Earth’s magn...
Magnetopause shadowing and wave-particle interactions are recognized as the two primary mechanisms f...
Energetic electrons are trapped in the Earth’s radiation belts which occupy a toroidal region betwee...
Electromagnetic Ion Cyclotron (EMIC) waves cause electron loss in the radiation belts by resonating ...
Abstract There has been increasing evidence for pitch angle scattering of relativistic electrons by...
Electromagnetic ion cyclotron (EMIC) waves which propagate at frequencies below the proton gyrofrequ...
Electromagnetic ion cyclotron (EMIC) waves which propagate at frequencies below the proton gyrofrequ...
The observations suggest that the dropout may have been caused by two separate mechanisms that opera...
In this study, we apply superposed epoch analysis to the 1.5-6.0 MeV electron flux dropout events ob...
Main phase flux dropouts often promote depletion of the outer electron radiation belt. The quantific...
Relativistic (>1 MeV) electron flux increases in the Earth's radiation belts are significantly under...
Outer zone radiation belt electrons can undergo gyroresonant interaction with various magnetospheric...