Electromagnetic disturbances observed near the dip region ahead of dipolarization front

Zhao, Dan; Fu, S. Y.; Sun, Weijie; Parks, G. K.; Zong, Qiugang; Shi, Quanqi; Pu, Z. Y.; Cui, Yan; Wu, Tong; Liu, Jiang; Zhou, Xuzhi

doi:10.1002/2016gl068033

Cited by 6 publications

(11 citation statements)

References 54 publications

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“…Around 13:04:54.00 UT, B z decreases from 0.37 to −0.92 nT within 0.9 s (from 13:04:53.5 to 13:04:54.4 UT, the time period when the magnetic field B z prior the DF decreases from the maximum value to the minimum value, as marked by the magenta dash lines), and the feature of B z depression is consistent with the character of the dip region ahead of the DF described in Figure 3 in Fu, Zhao, et al (2020). This implies that MMS observed a magnetic dip region ahead of the DF (Zhao et al, 2016;Schmid et al, 2019). By adopting the timing analysis method, the spatial scale of this dip region is estimated as 48.5 km, ∼0.1 λ i (λ i ∼489 km is the ion inertial length) and 0.02 ρ i (ρ i ∼ 1,980 km is the thermal proton gyroradius).…”

Section: Observationssupporting

confidence: 67%

“…Waves in the range of lower hybrid frequency ( f LH ; Divin et al., 2015; Huang, Fu, Yuan, 2015; Le Contel et al., 2017) are frequently observed at the DFs also. Below and around the f LH , the low frequency electromagnetic waves have been detected ahead of the DF (Zhao et al., 2016; Zhang et al., 2017). Whistler waves with frequency between f LH and electron cyclotron frequency ( f ce ) are often observed at and behind DFs (Chen et al., 2021; Deng et al., 2010; Fu et al., 2014; Grigorenko et al., 2020; Huang et al., 2012, 2016, 2019; Li et al., 2015; Liu et al., 2021).…”

Section: Introductionmentioning

confidence: 99%

“…Such study would help us to more fully understand the microphysics process (especially electron dynamics) around the DF. In the dip region, few low frequency fluctuations have been studied until now (Chen et al, 2021;Zhao et al, 2016;Zhang et al, 2017); however, high-frequency waves are not observed due to the limited time resolution of the instruments.…”

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confidence: 99%

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Observation of High‐Frequency Electrostatic Waves in the Dip Region Ahead of Dipolarization Front

et al. 2021

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Dipolarization front (DF) is a sharp magnetic structure featuring the increase of Bz in the magnetotail. Various types of waves have been observed around the DF. However, in the magnetic dip ahead of the DF, very few waves have been reported so far. In this study, we report broadband high‐frequency electrostatic waves in the dip region by using high resolution data from the magnetospheric multiscale (MMS) mission. The frequency range of these electrostatic emissions is higher than electron cyclotron frequency but lower than electron plasma frequency. These high‐frequency waves are quasi‐parallel propagating, and their parallel components dominate. Simultaneously, the measured field‐aligned electron distribution function (EDF) has a positive slope (df/dv|| > 0). The kinetic theory dispersion relationship curve based on the measured EDF reveals that the positive slope is responsible for the generation of high‐frequency electrostatic wave in the magnetic dip ahead of the DF.

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Section: Observationssupporting

confidence: 67%

Section: Introductionmentioning

confidence: 99%

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Observation of High‐Frequency Electrostatic Waves in the Dip Region Ahead of Dipolarization Front

et al. 2021

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“…In the earthward propagation of DFs, precursor signatures that include gradual enhancements in plasma density, velocity, and pressure are commonly detected ~20 to ~60 s prior to the sharp enhancement of B z (e.g., Ohtani et al, ; Zhao et al, ; Zhou et al, , ). These signatures have been interpreted as preexisting plasma sheet particles being accelerated and reflected by the approaching DF (Eastwood et al, ; P. Wu & Shay, ; Zhou et al, , ).…”

Section: Introductionmentioning

confidence: 99%

Oxygen Ion Reflection at Earthward Propagating Dipolarization Fronts in the Magnetotail

Zhao

Sun

et al. 2018

JGR Space Physics

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A dipolarization front (DF) is known as the leading edge of an earthward high‐speed flow with a sharp enhancement in the northward magnetic field (Bz). Analysis of an event observed by Cluster shows that the behavior of oxygen ions (O+) around the DF is very different from protons (H+). After the crossing of the DF, the O+ density decreases more gradually than H+. The distance between the density minimum of O+ and the DF layer is ~4 times longer than that of H+, which is close to their gyroradii ratio with the same energy. A flux dropout is observed in the O+ energy spectrum, whose energy dependence indicates that ions with higher energies can reach locations farther tailward of the DF. Similar variations are also seen in studies of 22 events in which a common pattern of ion properties is obtained by performing a superposed epoch analysis. Finally, using backward tracing test‐particle simulations, we reproduce the characteristics of the flux dropout and verify that the time dependence of the dropout is highly correlated with the gyromotion of different energy O+ behind the DF. All these results provide a further understanding of ion dynamics associated with DFs and suggest that the observed O+ ions are reflected within a half gyromotion in the central plasma sheet.

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“…The plasma sheet (Bame et al, ) in the Earth's magnetotail is a region full of plasma activities characterized by high‐speed plasma flows (Angelopoulos et al, ; Baumjohann et al, ), magnetic structures (Nakamura et al, ; Slavin et al, ), wave activities (Khotyaintsev et al, ; Zhao et al, ), and particle accelerations (Fu et al, ; Zhou et al, ). During the active times in the plasma sheet, both earthward and tailward flows are generated (Nagai et al, ).…”

Section: Introductionmentioning

confidence: 99%

Modulation of Whistler Mode Waves by Ion‐Scale Waves Observed in the Distant Magnetotail

Zhao

Parks

et al. 2020

JGR Space Physics

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Wave activities in tailward flows have been explored in the distant magnetotail at ~54 RE, where the coupling between whistler mode waves and ion‐scale waves was observed. The whistler mode waves periodically appeared at each cycle of the ion‐scale waves, and the electron distribution functions associated with the whistler mode waves showed enhancement in the direction parallel to background magnetic field. Wave analyses show that the field‐aligned electron components act as the energy source of the whistler mode waves. The ion‐scale waves are generated by the interaction of the hot ion beam with background ions. A likely candidate of the ion‐scale wave is the kinetic Alfven wave, which can generate the enhanced field‐aligned electron populations by the parallel electric field.

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Electromagnetic disturbances observed near the dip region ahead of dipolarization front

Cited by 6 publications

References 54 publications

Observation of High‐Frequency Electrostatic Waves in the Dip Region Ahead of Dipolarization Front

Observation of High‐Frequency Electrostatic Waves in the Dip Region Ahead of Dipolarization Front

Oxygen Ion Reflection at Earthward Propagating Dipolarization Fronts in the Magnetotail

Modulation of Whistler Mode Waves by Ion‐Scale Waves Observed in the Distant Magnetotail

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