Global electron content during solar cycle 23

Global electron content (GEC) as a new ionospheric parameter was first proposed by Afraimovich et al. [2006]. GEC is equal to the total number of electrons in the near-Earth space. GEC better than local parameters reflects the global response to a change in solar activity. It has been indicated that...

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Veröffentlicht in:	Geomagnetism and aeronomy 2008-04, Vol.48 (2), p.187-200
Hauptverfasser:	Afraimovich, E. L., Astafyeva, E. I., Zhivetiev, I. V., Oinats, A. V., Yasyukevich, Yu. V.
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container_title	Geomagnetism and aeronomy
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creator	Afraimovich, E. L. Astafyeva, E. I. Zhivetiev, I. V. Oinats, A. V. Yasyukevich, Yu. V.
description	Global electron content (GEC) as a new ionospheric parameter was first proposed by Afraimovich et al. [2006]. GEC is equal to the total number of electrons in the near-Earth space. GEC better than local parameters reflects the global response to a change in solar activity. It has been indicated that, during solar cycle 23, the GEC dynamics followed similar variations in the solar UV irradiance and F 10.7 index, including the 11-year cycle and 27-day variations. The dynamics of the regional electron content (REC) has been considered for three belts: the equatorial belt and two midlatitude belts in the Northern and Southern hemispheres (±30° and 30°–65° geomagnetic latitudes, respectively). In contrast to GEC, the annual REC component is clearly defined for the northern and southern midlatitude belts; the REC amplitude is comparable with the amplitude of the seasonal variations in the Northern Hemisphere and exceeds this amplitude in the Southern Hemisphere by a factor of ∼1.7. The dayside to nightside REC ratio, R ( t ), at the equator is a factor of 1.5 as low as such a GEC ratio, which indicates that the degree of nighttime ionization is higher, especially during the solar activity maximum. The pronounced annual cycle with the maximal R ( t ) value near 8.0 for the winter Southern Hemisphere and summer Northern Hemisphere is typical of midlatitudes.
doi_str_mv	10.1134/S0016793208020084
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The dynamics of the regional electron content (REC) has been considered for three belts: the equatorial belt and two midlatitude belts in the Northern and Southern hemispheres (±30° and 30°–65° geomagnetic latitudes, respectively). In contrast to GEC, the annual REC component is clearly defined for the northern and southern midlatitude belts; the REC amplitude is comparable with the amplitude of the seasonal variations in the Northern Hemisphere and exceeds this amplitude in the Southern Hemisphere by a factor of ∼1.7. The dayside to nightside REC ratio, R ( t ), at the equator is a factor of 1.5 as low as such a GEC ratio, which indicates that the degree of nighttime ionization is higher, especially during the solar activity maximum. 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title	Global electron content during solar cycle 23
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