Variability in the maximum height of the ionospheric F2-layer over Millstone Hill (September 1998-March 2000); influence from below and above

The basic aim of this ‘case study’ is to investigate the variability in the maximum height of the ionospheric F2-layer, hmF2, with periods of planetary waves (2–30 days), and to make an attempt to determine their origin. The hourly data of hmF2 above Millstone Hill (42.6° N, 71.5° W) during 01 Septe...

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Published inAnnales geophysicae (1988) Vol. 20; no. 11; pp. 1807 - 1819
Main Authors PANCHEVA, D, MITCHELL, N, CLARK, R. R, DROBJEVA, J, LASTOVICKA, J
Format Journal Article
LanguageEnglish
Published Katlenburg-Lindau European Geophysical Society 2002
European Geosciences Union
Copernicus Publications
Subjects
Earth Sciences
Earth, ocean, space
Exact sciences and technology
External geophysics
Ionospheric disturbances
Marine
Ocean, Atmosphere
Physics of the ionosphere
Sciences of the Universe
United States
North America
Massachusetts
America
Thermosphere
Zonal wind
Periodicity
Summer
Mesosphere
Semidiurnal tide
Ionospheric F region
Case study
Magnetic storm
Ionospheric disturbance
Neutral wind
Height
Planetary wave
Delay time
Geomagnetic activity
Ionospheric F2 layer
Geomagnetic disturbance
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Summary:The basic aim of this ‘case study’ is to investigate the variability in the maximum height of the ionospheric F2-layer, hmF2, with periods of planetary waves (2–30 days), and to make an attempt to determine their origin. The hourly data of hmF2 above Millstone Hill (42.6° N, 71.5° W) during 01 September 1998 - 31 March 2000 were used for analysis. Three types of disturbances are studied in detail: (i) the 27- day oscillations observed in the hmF2 above Millstone Hill are generated by the geomagnetic activity and by the global-scale 27-day wave present in the zonal mesosphere/lower thermosphere (MLT) neutral wind. The time delay between the 27-day oscillation in the zonal wind and that in the hmF2 is found to be 5–6 days, while between the 27-day oscillation in the geomagnetic activity and that in the hmF2 is found to be 0.8–1 day; (ii) the 16-day oscillation in the hmF2 observed during summer 1999 is probably generated by the global scale 16-day modulation of the semidiurnal tide observed in the MLT region during PSMOS campaign in June–August. We found that if the modulated semidiurnal tide mediates the planetary wave signature in the ionosphere, this planetary wave oscillation has to be best expressed in the amplitude and in the phase of the 12-h periodicity of the ionosphere; and (iii) the third type of disturbances studied is the quasi-2- day activity in the hmF2 that increases during geomagnetic disturbances. The strong pseudo diurnal periodicities generated during the geomagnetic storms can interact between each other and produce the quasi-2-day oscillations in the ionosphere.Key words. Ionosphere (ionosphere-atmosphere interactions; ionosphere-magnetoshpere interactions; wave propagation)
Bibliography:ObjectType-Article-2
SourceType-Scholarly Journals-1
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ISSN:0992-7689
1432-0576
1432-0576
DOI:10.5194/angeo-20-1807-2002