Your search keyword '"Endawoke Yizengaw"' showing total 2 results

1. Observations of ULF wave related equatorial electrojet and density fluctuations

Author

Mark B. Moldwin, R. F. Pfaff, A. Mebrahtu, Baylie Damtie, Eftyhia Zesta, C. M. Biouele, Endawoke Yizengaw, F. Anad, and Michael Hartinger

Subjects

Physics, Magnetometer, Equator, Magnetosphere, Equatorial electrojet, Geophysics, Atmospheric sciences, Physics::Geophysics, Magnetic field, law.invention, Solar wind, law, Physics::Space Physics, Ionosphere, Physics::Atmospheric and Oceanic Physics, Ultra low frequency

Abstract

Global magnetospheric Ultra Low Frequency (ULF) pulsations with frequencies in the Pc 4–5 range (f = 1.0–8 mHz) have been observed for decades in space and on Earth. ULF pulsations contribute to magnetospheric particle transport and diffusion and play an important role in magnetospheric dynamics. However, only a few studies have been performed on ionospheric observations of ULF wave-related perturbations in the vicinity of the equatorial region. In this paper we report on Pc5 wave related electric field and thus vertical drift velocity oscillations at the equator as observed by ground magnetometers and radar. We show that the magnetometer estimated equatorial ExB drift oscillate with the same frequency as ULF Pc5 waves, creating significant ionospheric density fluctuations. For independent confirmation of the vertical drift velocity fluctuation, we used JULIA 150 km radar drift velocities and found similar fluctuation with the period of 8–10 minutes. We also show ionospheric density fluctuations during the period when we observed ULF wave activities. All these demonstrate that the Pc5 wave can penetrate to the equatorial ionosphere and modulate the equatorial electrodynamics. Finally, in order to detect the ULF activities both on the ground and in space, we use ground-based magnetometer data from African Meridian B-field Education and Research (AMBER) and the South American Meridional B-field Array (SAMBA). From space, we use magnetic field observations from the GOES 12 and the Communication/Navigation Outage and Forecast System (C/NOFS) satellites. Using the WIND spacecraft as the upstream solar wind monitor, we present direct evidence that solar wind number density and ram pressure fluctuations observed far upstream from the terrestrial magnetosphere are the main drivers of ULF wave activity inside the magnetosphere. Finally, we show that the ULF waves in the same frequency range are observed in the magnetosphere by the geosynchronous GOES spacecraft, in the ionosphere by the equatorial C/NOFS satellite, and on the ground by ground-based magnetometers, indicating that the magnetospheric origin ULF wave can penetrate to the ground equatorial region and modulate the equatorial electrodynamics.

Published

2011

2. An investigation of ionospheric disturbances over South Africa during the magnetic storm on 15 May 2005

Author

Pierre Cilliers, Chigomezyo M. Ngwira, Lee-Anne McKinnell, Endawoke Yizengaw, and Ben D.L. Opperman

Subjects

Geomagnetic storm, Earth's magnetic field, Total electron content, Meteorology, TEC, Climatology, Storm, Ionosphere, F region, Ionosonde, Geology

Abstract

The effects of the 15 May 2005 severe geomagnetic storm on the South African ionosphere are studied using ground-based and satellite observations. Ionospheric disturbances have less frequently been investigated over mid-latitude regions. Recently, a number of studies investigated their evolution and generation over these regions. This paper reports on the first investigation of travelling ionospheric disturbances (TIDs) over mid-latitude South Africa. Using Global Positioning System (GPS)-derived total electron content (TEC) variations from the South African network of dual frequency GPS receivers, we were able to examine the effects of the disturbance on the quiet-time TEC. Two TEC enhancements were observed at low- and mid-latitudes: the first observed between 30–45°S geomagnetic latitudes associated with equatorward neutral winds and the passage of a TID, and the second TEC enhancement associated with a second TID. In addition, the F-region critical frequency (foF2) values observed at two ionosonde stations show that the ionospheric response as seen by ionosondes was different from that of the TEC response during the disturbance period. The dissimilarity between the TEC and the foF2 suggests that two competing drivers existed, i.e., the westward electric field and equatorward neutral wind effects.

Published

2011