Magnetospheric source region of discrete auroras inferred from their relationship with isotropy boundaries of energetic particles

Yahnin, A. G.; Сергеев, В. А.; Gvozdevsky, B. B.; Vennerstrøm, S.

doi:10.1007/s00585-997-0943-z

Cited by 63 publications

(45 citation statements)

References 34 publications

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“…Such consistency is unlikely to be fortuitous only. As a matter of fact, the above result is fully consistent with a number of existing observations and theoretical proposals that an equatorward-most arc likely maps to somewhere in the earthward portion of a stretched thin current sheet, on the verge of a transition into the quasidipolar inner magnetosphere (Lui and Burrows, 1978;Galperin et al, 1992;Yahnin et al, 1997;Galperin and Bosqued, 1999;Sergeev et al, 2012). In particular, using an event-adaptive magnetic field model (Kubyshkina et al, 2011) tuned by THEMIS, GOES, and NOAA observations, Sergeev et al (2012) mapped the prebreakup arc to the CPS, and found that the AR was situated at the outer edge of a "magnetic wall" region with strong B z and R c gradient.…”

Section: Discussionsupporting

confidence: 89%

“…Compared to the above-inferred location of the earthward boundary of AR at ∼ 05:11 UTC; X ∼ −6.7; R ∼ 9.8 R E , even taking into account a slow migration of the NTR during the two measurement epochs, we are able to deduce the following key inference on the relative location of the AR with respect to the NTR: the AR itself is embedded in a highly stretched current sheet region with a relatively stable B z , but its earthward edge is on the verge of a transition into a quasi-dipolar magnetosphere with much steepened B z gradients. The above inference of the AR location is fully consistent with a number of existing observations and theoretical proposals that an equatorward-most arc likely maps to the earthward portion of a stretched current sheet region, at the periphery of the quasi-dipolar magnetosphere (Lui and Burrows, 1978;Galperin et al, 1992;Yahnin et al, 1997;Galperin and Bosqued, 1999;Sergeev et al, 2012).…”

Section: April 2009 Eventsupporting

confidence: 88%

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Quasi-parallel electron beams and their possible application in inferring the auroral arc's root in the magnetosphere

Liang

Jiang²,

Donovan

et al. 2013

Ann. Geophys.

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In this study we investigate the upgoing electron beams at the topside ionosphere and their counterpart feature, the bidirectional quasi-parallel electron beams (QPEB) in the equatorial magnetosphere, with highlight on their potential application in estimating the location of the arc's root (AR) in the magnetotail central plasma sheet (CPS). We infer from FAST data that the upgoing electron beam is often found in the equatorward vicinity of the inverted-V arc. On the premise of such a scenario, we propose a method to estimate the location of the AR from available magnetospheric measurements by assuming that the tailward boundary of the QPEB demarcates the earthward boundary of the AR. We report two events with THEMIS observations of QPEBs in the magnetotail CPS, and demonstrate how to use the QPEB features, together with the magnetic signatures of the current circuit constituted by the QPEB and arc, to estimate the earthward boundary of the AR. We find that the estimated earthward boundary of AR is situated at the periphery of a quasi-dipolar magnetosphere characterized by a strong B_z gradient. This finding is consistent with previously existing proposals on the possible AR location in the tail (e.g., Lui and Burrows, 1978; Sergeev et al., 2012)

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Section: Discussionsupporting

confidence: 89%

Section: April 2009 Eventsupporting

confidence: 88%

Quasi-parallel electron beams and their possible application in inferring the auroral arc's root in the magnetosphere

Liang

Jiang²,

Donovan

et al. 2013

Ann. Geophys.

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“…The region where precipitation flux is over 10 0 mW/m 2 is identified as auroral oval, whereas that where the flux is below the value is identified as subauroral region (Yahnin et al 1997). In this manner, we selected only subauroral region flows.…”

Section: Discussionmentioning

confidence: 99%

Occurrence characteristics and lowest speed limit of subauroral polarization stream (SAPS) observed by the SuperDARN Hokkaido East radar

2015

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We investigate the characteristics of the subauroral polarization stream (SAPS), with focus on the relationship between geomagnetic parameters and occurrence characteristics of SAPS. This study's observations were made using the Super Dual Auroral Radar Network (SuperDARN) Hokkaido East radar, which can observe the Far East region of Russia and has been in operation since 2006. In particular, we identify the lowest limit of SAPS speed, which has not been discussed in previous literature, in order to examine the lowest threshold of electric field able to generate SAPS as a result of magnetosphere-ionosphere (M-I) coupling. In order to conduct a comprehensive investigation of SAPS occurrence characteristics, we analyzed events with wider ranges of velocity and magnetic latitude (MLAT) than those in previous studies. As a result of quantitative estimation, we found two categories of westward flows that were reasonably separated using a speed threshold of 150-200 m/s. For the faster flows above the speed threshold, there is a clear correlation between MLAT and SYM-H geomagnetic index, whereas for the slower flows, there is no such correlation. The faster flows are considered to be SAPS, whereas the slower flows are probably associated with mid-latitude F-region ionospheric irregularities not directly related to storms or substorms. This slowest limit of SAPS gives us a minimum electric field of 7.5-10 mV/m that generates SAPS. However, this field strength is not strong enough to cause frictional heating, which is generally considered to be a crucial mechanism for generating SAPS. This result suggests that frictional heating is not always necessary to generate SAPS.

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“…Early in situ observations of CS thinning around x =−10 to −12 R E in the near-Earth magnetosphere [Mitchell et al, 1990;Pulkkinen et al, 1991;Sergeev et al, 1993;Sanny et al, 1994] and estimates of equatorial magnetic field gradients from precipitation models [Sergeev et al, 1990;Yahnin et al, 1997] suggested that CS thickness can decrease to 500-1000 km (see, also, review by Ganushkina et al [2015]). This scale is comparable to or even smaller than the local ion gyroradius.…”

Section: Introductionmentioning

confidence: 99%

Properties of current sheet thinning at x ∼− 10 to −12 R_E

2016

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We report on Time History of Events and Macroscale Interactions during Substorms (THEMIS) observations of current sheet thinning in Earth's magnetotail at around x =− 10 to −12 Earth radii. The THEMIS spacecraft configuration in October–December 2015 allows us to construct both gradients that contribute to the cross‐tail current density jy=μ0−1(∂Bx/∂z−∂Bz/∂x) (GSM coordinates). For 17 events when the spacecraft observed a gradual Bz decrease and jy increase, we find the following average scaling relations: for the current density jy∼Bz−7/4, for the lobe magnetic field BL∼Bz−1/4, and for the plasma density ni∼Bz−3/4. We show that the temperature of ions and electrons decreases and the plasma pressure gradient ∂p/∂x rapidly increases during current sheet thinning. The scale Lx=(∂lnp/∂x)−1 decreases a few thousand kilometers. We also consider current carriers in thinning current sheets: both ion and electron current‐dominated current sheets, preferentially located near dusk and midnight, respectively, are found.

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Magnetospheric source region of discrete auroras inferred from their relationship with isotropy boundaries of energetic particles

Cited by 63 publications

References 34 publications

Quasi-parallel electron beams and their possible application in inferring the auroral arc's root in the magnetosphere

Quasi-parallel electron beams and their possible application in inferring the auroral arc's root in the magnetosphere

Occurrence characteristics and lowest speed limit of subauroral polarization stream (SAPS) observed by the SuperDARN Hokkaido East radar

Properties of current sheet thinning at x ∼− 10 to −12 R_E

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Magnetospheric source region of discrete auroras inferred from their relationship with isotropy boundaries of energetic particles

Cited by 63 publications

References 34 publications

Quasi-parallel electron beams and their possible application in inferring the auroral arc's root in the magnetosphere

Quasi-parallel electron beams and their possible application in inferring the auroral arc's root in the magnetosphere

Occurrence characteristics and lowest speed limit of subauroral polarization stream (SAPS) observed by the SuperDARN Hokkaido East radar

Properties of current sheet thinning at x ∼− 10 to −12 RE

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Properties of current sheet thinning at x ∼− 10 to −12 R_E