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1. Simultaneous Development of Multiple Auroral Substorms: Double Auroral Bulge Formation

   https://doi.org/10.1029/2020JA028883  

   Ohtani, S.; Gjerloev, J_W; McWilliams, K_A; Ruohoniemi, J_M; Frey, H_U (May 2021, Journal of Geophysical Research: Space Physics)

   Abstract The expansion phase of auroral substorms is characterized by the formation of an auroral bulge, and it is generally considered that a single bulge forms following each substorm onset. However, we find that occasionally two auroral intensifications takes place close in time but apart in space leading to the formation of double auroral bulges, which later merge into one large bulge. We report three such events. In those events the westward auroral electrojet intensified in each auroral bulge, and geosynchronous magnetic field dipolarized in the same sector. It appears that two substorms took place simultaneously, and each substorm was accompanied by the formation of its own substorm current wedge system. This finding strongly suggests that the initiation of auroral substorms is a local process, and there is no global reference frame for their development. For example, ideas such as (i) the auroralbreakup takes place in the vicinity of the Harang reversal and (ii) the westward traveling surge maps to the interface between the plasma sheet and low‐latitude boundary layer, do not necessarily hold for every substorm. Even if those ideas may be suggestive of causal magnetospheric processes, the reference structures themselves are probably not essential. It is also found that despite the formation of two distinct auroral bulges, the overall magnetosphere‐ionosphere current system is represented by one globally coherent system, and we suggest that its structure is determined by the relative intensities and locations of the two substorm current wedges that correspond to the individual auroral bulges. 

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2. Dawnside Auroral Polarization Streams

   https://doi.org/10.1029/2019JA027742  

   Liu, Jiang; Lyons, L. R.; Wang, Chih‐Ping; Hairston, M. R.; Zhang, Yongliang; Zou, Ying (August 2020, Journal of Geophysical Research: Space Physics)

   null (Ed.)
3. Flickering Low Frequency Auroral Hiss

   https://doi.org/10.1029/2020JA029098  

   LaBelle, James (April 2021, Journal of Geophysical Research: Space Physics)

   Abstract A low‐ and medium‐frequency (LF/MF) receiving system at South Pole Station, using a wide‐beam dipole antenna, measured continuous fully sampled waveforms of more than 100 LF auroral hiss events between June and October 2019. Spectra of fluctuations of LF auroral hiss intensity at selected frequencies between 110 and 530 kHz showed these are broadband, with spectral power monotonically decreasing to an upper bound typically 20–60 Hz, comparable to frequencies reported for optical flickering aurora. Occasionally intervals of periodic fluctuations in auroral hiss intensity occurred, in most cases lasting only tens of cycles. On September 1, 2019, periodic fluctuations lasted thousands of cycles during two 30‐s intervals, at frequencies 125–145 Hz. Close examination showed these to be dispersed with low frequencies arriving before high frequencies by approximately 4.5 ms per 100 kHz. Ray‐tracing calculations and consideration of the Temerin et al. (1986, 1993) mechanisms of flickering aurora shows that the September 1 flickering auroral hiss observations are consistent with resonant amplification of whistler mode noise by an electron beam accelerated and modulated by electromagnetic proton cyclotron waves originating near 4,500 km, with the wave excitation taking place at 2,000–3,000 km. 

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4. Mesoscale Auroral Curls in Antarctica

   https://doi.org/10.1029/2023GL107889  

   Li, Xing‐Yu; Zong, Qiu‐Gang; Hu, Ze‐Jun; Wang, Yong‐Fu; Liu, Jian‐Jun; Zhou, Xu‐Zhi; Yue, Chao; Wang, Shan; Xie, Zi‐Kang; Zhao, Xing‐Xin; et al (May 2024, Geophysical Research Letters)

   Abstract The morphology and motion of auroras have been widely studied due to their indications on magnetospheric processes. Here, we report a new kind of “auroral curls,” which have wavelengths in the mesoscale (∼100 km) and propagate azimuthally. Utilizing data from the Chinese Antarctic Zhongshan Station (the all‐sky imager and the high‐frequency radar), the Active Magnetosphere and Planetary Electrodynamics Response Experiment and the Defense Meteorological Satellite Program, we analyze an event occurred on 23 April 2019. We find these curls are fine structures in the poleward boundary of multiple arcs. Corresponding field‐aligned currents manifest as a series of longitudinally arranged pairs, while ionospheric flow velocities nearby oscillate with periods in the Pc 5 band. Observational evidence suggests these curls are connected with ultra‐low frequency (ULF) waves, which opens the possibility of using auroras to globally image ULF waves. 

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5. Field‐Aligned Currents in Auroral Vortices

   https://doi.org/10.1029/2020JA028583  

   Johnson, Jay R.; Wing, Simon; Delamere, Peter; Petrinec, Steven; Kavosi, Shiva (February 2021, Journal of Geophysical Research: Space Physics)

   null (Ed.)