Time scaling of the electron flux increase at GEO: The local energy diffusion model vs observations

M. A. Balikhin; M. Gedalin; G. D. Reeves; R. J. Boynton; S. A. Billings

doi:10.1029/2012JA018114

Time scaling of the electron flux increase at GEO: The local energy diffusion model vs observations

M. A. Balikhin, M. Gedalin, G. D. Reeves, R. J. Boynton, S. A. Billings

Department of Physics

Research output: Contribution to journal › Article › peer-review

27 Scopus citations

Abstract

The characteristic time scaling of the electron flux evolution at geosynchronous orbit (GEO), resulting from the quasilinear wave-particle interaction, is investigated. The upper limit of the electron flux increase rate, due to the interaction with waves, is deduced from the energy diffusion equation (EDE). Such a time scaling allows for a comparison with experimentally measured fluxes of energetic electrons at GEO. It is shown that the analytically deduced time scaling is too slow to explain the observed increase in fluxes. It is concluded that radial diffusion plays the most significant role in the build up of the energetic electrons population at GEO. However, this conclusion is only justified if the seed population energies are very low.

Original language	English
Article number	A10208
Journal	Journal of Geophysical Research: Space Physics
Volume	117
Issue number	10
DOIs	https://doi.org/10.1029/2012JA018114
State	Published - 1 Jan 2012

ASJC Scopus subject areas

Geophysics
Space and Planetary Science

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title = "Time scaling of the electron flux increase at GEO: The local energy diffusion model vs observations",

abstract = "The characteristic time scaling of the electron flux evolution at geosynchronous orbit (GEO), resulting from the quasilinear wave-particle interaction, is investigated. The upper limit of the electron flux increase rate, due to the interaction with waves, is deduced from the energy diffusion equation (EDE). Such a time scaling allows for a comparison with experimentally measured fluxes of energetic electrons at GEO. It is shown that the analytically deduced time scaling is too slow to explain the observed increase in fluxes. It is concluded that radial diffusion plays the most significant role in the build up of the energetic electrons population at GEO. However, this conclusion is only justified if the seed population energies are very low.",

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AU - Balikhin, M. A.

AU - Gedalin, M.

AU - Reeves, G. D.

AU - Boynton, R. J.

AU - Billings, S. A.

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AB - The characteristic time scaling of the electron flux evolution at geosynchronous orbit (GEO), resulting from the quasilinear wave-particle interaction, is investigated. The upper limit of the electron flux increase rate, due to the interaction with waves, is deduced from the energy diffusion equation (EDE). Such a time scaling allows for a comparison with experimentally measured fluxes of energetic electrons at GEO. It is shown that the analytically deduced time scaling is too slow to explain the observed increase in fluxes. It is concluded that radial diffusion plays the most significant role in the build up of the energetic electrons population at GEO. However, this conclusion is only justified if the seed population energies are very low.

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Time scaling of the electron flux increase at GEO: The local energy diffusion model vs observations

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