Abstract
We present observations of auroral omega bands on 28 September 2009. Although generally associated with the substorm recovery phase and typically observed in the morning sector, the features presented here occurred just after expansion phase onset and were observed in the midnight sector, dawnward of the onset region. An all-sky imager located in northeastern Iceland revealed that the omega bands were similar to 150 x 200 km in size and propagated eastward at similar to 0.4 km s(-1) while a colocated ground magnetometer recorded the simultaneous occurrence of Ps6 pulsations. Although somewhat smaller and slower moving than the majority of previously reported omega bands, the observed structures are clear examples of this phenomenon, albeit in an atypical location and unusually early in the substorm cycle. The THEMIS C probe provided detailed measurements of the upstream interplanetary environment, while the Cluster satellites were located in the tail plasma sheet conjugate to the ground-based all-sky imager. The Cluster satellites observed bursts of 0.1-3 keV electrons moving parallel to the magnetic field toward the Northern Hemisphere auroral ionosphere; these bursts were associated with increased levels of field-aligned Poynting flux. The in situ measurements are consistent with electron acceleration via shear Alfven waves in the plasma sheet similar to 8 R-E tailward of the Earth. Although a one-to-one association between auroral and magnetospheric features was not found, our observations suggest that Alfven waves in the plasma sheet are responsible for field-aligned currents that cause Ps6 pulsations and auroral brightening in the ionosphere. Our findings agree with the conclusions of earlier studies that auroral omega bands have a source mechanism in the midtail plasma sheet.
Highlights
[1] We present observations of auroral omega bands on 28 September 2009
The omega bands studied are slightly unusual in that they were observed in the midnight (21–03 magnetic local time (MLT)) sector ionosphere, rather than the morning (03–09 MLT) sector, and occurred shortly after a substorm expansion phase onset/intensification
[10] to reveal the magnetic perturbations associated with auroral features observed by the above experiments, we exploit 1 s resolution ground magnetic field measurements from a fluxgate magnetometer colocated with the Tjörnes Rainbow all‐sky imager (ASI) and deployed by the Japanese National Institute of Polar Research (NIPR) [Sato and Saemundsson, 1984]
Summary
[2] Auroral omega bands were first reported as a distinct class of auroral structure by Akasofu and Kimball [1964]. The omega bands studied are slightly unusual in that they were observed in the midnight (21–03 MLT) sector ionosphere, rather than the morning (03–09 MLT) sector, and occurred shortly after a substorm expansion phase onset/intensification (rather than during a substorm recovery phase). Typically 400–1000 km in size, are usually observed propagating eastward (i.e., dawnward) at speeds of 0.4–2 km s−1 in the morning sector auroral zone and are generally associated with the recovery phase of magnetospheric substorms [e.g., Vanhamäki et al, 2009, and references therein]. [10] to reveal the magnetic perturbations associated with auroral features observed by the above experiments, we exploit 1 s resolution ground magnetic field measurements from a fluxgate magnetometer colocated with the Tjörnes Rainbow ASI and deployed by the Japanese National Institute of Polar Research (NIPR) [Sato and Saemundsson, 1984]. The most recent upstream (PSW, IMF BY, IMF BZ observed by THEMIS C) and geomagnetic (Dst) data are selected as inputs to calculate the footprint positions at a 1 s resolution
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