Arase Observation of the Source Region of Auroral Arcs and Diffuse Auroras in the Inner Magnetosphere

Shiokawa, K.; Nosé, M.; Imajo, Shun; Tanaka, Yoshimasa; Hosokawa, K.; Connors, Martin; Engebretson, M. J.; Kazama, Y.; Wang, S. Y.; Tam, Sunny Wing-Yee; Chang, T. F.; Wang, Bo Jhou; Asamura, Kazushi; Kasahara, Satoshi; Yokota, Shoichiro; Hori, Tomoaki; Keika, K.; Kasaba, Yasumasa; Motomizu, Shoji; Kasahara, Yoshiya; Matsuoka, A.; Shinohara, I.

doi:10.1029/2019ja027310

Cited by 10 publications

(14 citation statements)

References 70 publications

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“…Using test particle simulations, Birn et al (2014) has demonstrated formation of the field-aligned distribution of thermal electrons (with energies of tens of keV down to sub-keV) through adiabatic acceleration associated with dipolarization fronts. Thus, we cannot rule out the contribution of adiabatic effects to the formation of field-aligned electrons in our event (see also Shiokawa et al, 2020).…”

Section: Geophysical Research Lettersmentioning

confidence: 93%

Potential Evidence of Low‐Energy Electron Scattering and Ionospheric Precipitation by Time Domain Structures

Shen

Artemyev

Zhang

et al. 2020

Geophysical Research Letters

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Plasma sheet electron precipitation is critical in magnetosphere‐ionosphere coupling and has long been attributed to electron scattering by whistler‐mode and electron cyclotron harmonic waves. Recent observations have revealed that time domain structures (TDSs) that appear as broadband electrostatic fluctuations may also scatter plasma sheet electrons. However, there has been no observational evidence of TDS scattering electrons into the ionosphere. This study presents potential evidence from conjugate observations between the Time History of Events and Macroscale Interactions during Substorms (THEMIS) mission and the low‐altitude Enhanced Polar Outflow Probe (e‐POP) spacecraft. During the five events presented, THEMIS observed intense electron injections accompanied by TDSs, while e‐POP captured precipitation of plasma sheet electrons with energies ∼100–325 eV over a broad pitch angle range. The observed TDSs can efficiently scatter these electrons exceeding the strong diffusion limit. Our results suggest that TDSs may contribute to plasma sheet electron scattering around times of injections.

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Section: Geophysical Research Lettersmentioning

confidence: 93%

Potential Evidence of Low‐Energy Electron Scattering and Ionospheric Precipitation by Time Domain Structures

Shen

Artemyev

Zhang

et al. 2020

Geophysical Research Letters

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“…9 Faculty of Engineering, Kyushu Institute of Technology, 1-1 Sensui-cho, Tobata-ku, Kitakyushu, Fukuoka 804-8550, Japan. 10 Research Institute for Sustainable Humanosphere, Kyoto University, Gokasho, Uji, Kyoto 611-0011, Japan. * email: imajos@isee.nagoya-u.ac.jp A typical representation of the acceleration region observed by previous low altitude satellites is as follows 6 .…”

Section: Openmentioning

confidence: 99%

“…Such an acceleration region is assumed to lie in the transition region between ionospheric and magnetospheric plasmas, typically at 1000-20,000 km altitudes 1 . However, there have been several reports of signatures reminiscent of potential-driven acceleration above 20,000 km, outside the ionosphere-magnetosphere transition region [7][8][9][10] . It is unclear whether electrons accelerated from such high altitudes can precipitate to the ionosphere and excite auroral emissions, owing to the small loss cone in the region.…”

Section: Openmentioning

confidence: 99%

Active auroral arc powered by accelerated electrons from very high altitudes

Imajo

Miyoshi

Kazama

et al. 2021

Sci Rep

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Bright, discrete, thin auroral arcs are a typical form of auroras in nightside polar regions. Their light is produced by magnetospheric electrons, accelerated downward to obtain energies of several kilo electron volts by a quasi-static electric field. These electrons collide with and excite thermosphere atoms to higher energy states at altitude of ~ 100 km; relaxation from these states produces the auroral light. The electric potential accelerating the aurora-producing electrons has been reported to lie immediately above the ionosphere, at a few altitudes of thousand kilometres1. However, the highest altitude at which the precipitating electron is accelerated by the parallel potential drop is still unclear. Here, we show that active auroral arcs are powered by electrons accelerated at altitudes reaching greater than 30,000 km. We employ high-angular resolution electron observations achieved by the Arase satellite in the magnetosphere and optical observations of the aurora from a ground-based all-sky imager. Our observations of electron properties and dynamics resemble those of electron potential acceleration reported from low-altitude satellites except that the acceleration region is much higher than previously assumed. This shows that the dominant auroral acceleration region can extend far above a few thousand kilometres, well within the magnetospheric plasma proper, suggesting formation of the acceleration region by some unknown magnetospheric mechanisms.

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“…With the RBSP-B, they observed an upward field-aligned current (FAC) located within the tailward part of a spatially localized plasma pressure peak, suggesting the role of local pressure gradients as a driver for the upward FAC in the arcs. Shiokawa et al (2020) comprehensively analyzed the source region of auroral arcs during a substorm expansion phase using the Arase satellite at a geocentric distance of ∼5.8 R E and ∼−17° MLAT. They found strong electric field fluctuations with large earthward/tailward Poynting fluxes and bidirectional electrons that can be considered as earthward plasma injections through the Fermi-type electron acceleration at energies above a few keV and upward field-aligned potential difference at energies below a few keV.…”

mentioning

confidence: 99%

Signatures of Auroral Potential Structure Extending Through the Near‐Equatorial Inner Magnetosphere

Imajo

Miyoshi

Asamura

et al. 2022

Geophysical Research Letters

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The quasi-electrostatic electric field parallel to the magnetic field is a fundamental element of the auroral processes of discrete auroral arcs and the magnetosphere-ionosphere current systems. Typical phenomena observed on auroral arcs, such as a converging perpendicular electric field (Mozer et al., 1977), inverted-V shape energy spectra of downgoing electrons (Frank & Ackerson, 1971), and upflowing ion beams (Shelley et al., 1976), have supported the view of a U-shaped potential structure (e.g., Gurnett, 1972;Karlsson et al., 2020). Such a potential structure causes a decoupling of the plasma convection between above and below the region of the parallel electric field, known as the auroral acceleration region (e.g., Haerendel, 2007). Thus, the altitude at which the legs of the U-shaped potential surface extend is an important issue when considering the influence of the auroral potential structure on the magnetospheric plasma dynamics. Janhunen et al. (1999) concluded that converging electric fields were rarely observed at geocentric distances above 4R E using the POLAR satellite. They suggested that an O-shaped potential explains the low occurrence of high-altitude converging electric fields. In contrast, a more comprehensive study by Janhunen et al. (2004) found that the converging electric field could occur even at high altitudes when the geomagnetic activity is high. Recently, using the Arase satellite, Imajo et al. ( 2021) found

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Arase Observation of the Source Region of Auroral Arcs and Diffuse Auroras in the Inner Magnetosphere

Cited by 10 publications

References 70 publications

Potential Evidence of Low‐Energy Electron Scattering and Ionospheric Precipitation by Time Domain Structures

Potential Evidence of Low‐Energy Electron Scattering and Ionospheric Precipitation by Time Domain Structures

Active auroral arc powered by accelerated electrons from very high altitudes

Signatures of Auroral Potential Structure Extending Through the Near‐Equatorial Inner Magnetosphere

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