Simultaneous Rocket and Scintillation Observations of Plasma Irregularities Associated With a Reversed Flow Event in the Cusp Ionosphere

Simultaneous Rocket and Scintillation Observations of Plasma Irregularities Associated With a Reversed Flow Event in the Cusp Ionosphere

We present an overview of the ionospheric conditions during the launch of the Investigation of Cusp Irregularities 3 (ICI‐3) sounding rocket. ICI‐3 was launched from Ny‐Ålesund, Svalbard, at 7:21.31 UT on 3 December 2011. The objective of ICI‐3 was to intersect the reversed flow event (RFE), which i...

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Veröffentlicht in:Journal of geophysical research. Space physics 2019-08, Vol.124 (8), p.7098-7111
Hauptverfasser: Jin, Yaqi, Moen, Jøran I., Spicher, Andres, Oksavik, Kjellmar, Miloch, Wojciech J., Clausen, Lasse B. N., Pożoga, Mariusz, Saito, Yoshifumi
Format: Artikel
Sprache:eng
Schlagworte:
cusp ionosphere
Cusps
Electron density
Elevation angle
Field of view
Flow channels
Frequency ranges
Global positioning systems
GPS
Interplanetary magnetic field
Ionosphere
Ionospheric conditions
Ionospheric irregularities
Irregularities
Magnetic fields
Power spectra
Radar
Reversed flow
reversed flow event
Satellite navigation systems
Satellite tracking
Scintillation
Sounding rockets
Variation
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Zusammenfassung:We present an overview of the ionospheric conditions during the launch of the Investigation of Cusp Irregularities 3 (ICI‐3) sounding rocket. ICI‐3 was launched from Ny‐Ålesund, Svalbard, at 7:21.31 UT on 3 December 2011. The objective of ICI‐3 was to intersect the reversed flow event (RFE), which is thought to be an important source for the rapid development of ionospheric irregularities in the cusp ionosphere. The interplanetary magnetic field was characterized by strongly negative Bz and weakly negative By. The EISCAT Svalbard radar (ESR) 32‐m beam was operating in a fast azimuth sweep mode between 180° (south) and 300° (northwest) at an elevation angle of 30°. The ESR observed a series of RFEs as westward flow channels that were opposed to the large‐scale eastward plasma flow in the prenoon sector. ICI‐3 intersected the first RFE in the ESR field of view and observed flow structures that were consistent with the ESR observations. Furthermore, ICI‐3 revealed finer‐scale flow structures inside the RFE. The high‐resolution electron density data show intense fluctuations at all scales throughout the RFE. The ionospheric pierce point of the GPS satellite PRN30, which was tracked at Hornsund, intersected the RFE at the same time. The GPS scintillation data show moderate phase scintillations and weak amplitude scintillations. A comparison of the power spectra reveals a good match between the ground‐based GPS carrier phase measurements and the spectral slope of the in situ electron density data in the lower frequency range. It demonstrates the possibility of modelling GPS scintillations from high‐resolution in situ electron density data. Key Points RFE is associated with sharp flow shear and particle precipitation which result in GPS scintillations The spectral slopes between scintillation and in situ measurements are consistent with the phase screen theory The study suggests that it is possible to model GPS scintillations from high‐resolution in situ electron density data
ISSN:2169-9380
2169-9402
DOI:10.1029/2019JA026942