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Source and seed populations for relativistic electrons: Their roles in radiation belt changes

A. N. JaynesLaboratory for Atmospheric and Space Physics University of Colorado Boulder Boulder Colorado USAD. N. BakerLaboratory for Atmospheric and Space Physics University of Colorado Boulder Boulder Colorado USAH. J. SingerNOAA Space Weather Prediction Center Boulder Colorado USAJ. V. RodriguezCooperative Institute for Research in Environmental Sciences University of Colorado Boulder Boulder Colorado USAP. T. M. Loto'aniuCooperative Institute for Research in Environmental Sciences University of Colorado Boulder Boulder Colorado USAA. AliLaboratory for Atmospheric and Space Physics University of Colorado Boulder Boulder Colorado USAS. R. ElkingtonLaboratory for Atmospheric and Space Physics University of Colorado Boulder Boulder Colorado USAXinlin LiLaboratory for Atmospheric and Space Physics University of Colorado Boulder Boulder Colorado USAS. G. KanekalNASA Goddard Space Flight Center Greenbelt Maryland USAS. G. ClaudepierreSpace Sciences Department Aerospace Corporation Los Angeles California USAJ. F. FennellSpace Sciences Department Aerospace Corporation Los Angeles California USAWen LiDepartment of Atmospheric and Oceanic Sciences University of California Los Angeles California USAR. M. ThorneDepartment of Atmospheric and Oceanic Sciences University of California Los Angeles California USAC. A. KletzingDepartment of Physics and Astronomy University of Iowa Iowa City Iowa USAH. E. SpenceInstitute for Study of Earth, Oceans, and Space University of New Hampshire Durham New Hampshire USAG. D. ReevesSpace Science and Applications Group Los Alamos National Laboratory Los Alamos New Mexico USA
2015en
ABI

Аннотация

Abstract Strong enhancements of outer Van Allen belt electrons have been shown to have a clear dependence on solar wind speed and on the duration of southward interplanetary magnetic field. However, individual case study analyses also have demonstrated that many geomagnetic storms produce little in the way of outer belt enhancements and, in fact, may produce substantial losses of relativistic electrons. In this study, focused upon a key period in August–September 2014, we use GOES geostationary orbit electron flux data and Van Allen Probes particle and fields data to study the process of radiation belt electron acceleration. One particular interval, 13–22 September, initiated by a short‐lived geomagnetic storm and characterized by a long period of primarily northward interplanetary magnetic field (IMF), showed strong depletion of relativistic electrons (including an unprecedented observation of long‐lasting depletion at geostationary orbit) while an immediately preceding, and another immediately subsequent, storm showed strong radiation belt enhancement. We demonstrate with these data that two distinct electron populations resulting from magnetospheric substorm activity are crucial elements in the ultimate acceleration of highly relativistic electrons in the outer belt: the source population (tens of keV) that give rise to VLF wave growth and the seed population (hundreds of keV) that are, in turn, accelerated through VLF wave interactions to much higher energies. ULF waves may also play a role by either inhibiting or enhancing this process through radial diffusion effects. If any components of the inner magnetospheric accelerator happen to be absent, the relativistic radiation belt enhancement fails to materialize.

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