Theoretical Study of Interhemispheric Electron Bouncing Within Pulsating Aurora

Theoretical Study of Interhemispheric Electron Bouncing Within Pulsating Aurora

Wave-particle interaction processes in the equatorial magnetosphere initiate time-dependent electron precipitation in the pulsating aurora. These electrons enter loss-cone and bounce between the two magnetically conjugate hemispheres, collide with the atmospheric constituents, and introduce addition...

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Veröffentlicht in:Geophysical research letters 2023-05, Vol.50 (9), p.n/a
Hauptverfasser: Khazanov, George V, Chu, Mike, Samara, Marilia, Michell, Robert G
Format: Artikel
Sprache:eng
Schlagworte:
Auroras
Bouncing
Cerebral hemispheres
Communication
Conjugates
Coupling
Distribution functions
Electromagnetic radiation
Electron distribution
Electron precipitation
Electron transport
Electrons
Energy
Energy coupling
Geophysics
Hemispheres
Ionosphere
Magnetic fields
Magnetospheres
magnetosphere‐ionosphere coupling
Optical observations
Particle interactions
Precipitation
pulsating aurora
Time dependence
Transport
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Zusammenfassung:Wave-particle interaction processes in the equatorial magnetosphere initiate time-dependent electron precipitation in the pulsating aurora. These electrons enter loss-cone and bounce between the two magnetically conjugate hemispheres, collide with the atmospheric constituents, and introduce additional time scales in electron precipitation dynamics. In this letter we present preliminary results of pulsating aurora formation using the time-dependent SuperThermal Electron Transport code, which considers the magnetosphere-ionosphere-atmosphere energy coupling between the two magnetically conjugate regions and discuss their contribution to the peculiarities of electron distribution function formation within the pulsating aurora.
ISSN:0094-8276
1944-8007
DOI:10.1029/2023GL103019