Propagation of small size magnetic holes in the magnetospheric plasma sheet

Geophysical Research Letters

Shi

Guo

et al. 2018

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The sudden enhancements of magnetic strength, named magnetic peaks (MPs), are often observed in the magnetosheath of magnetized planets. They are usually identified as flux ropes (FRs) or magnetic mirror mode structures. Previous studies of MPs are mostly on the magnetohydrodynamics (MHD) scale. In this study, an electron scale MP is reported in the Earth magnetosheath. We present a typical case with a scale of ~7 electron gyroradii and a duration of ~0.18 s. A strong magnetic disturbance and associated electrical current are detected. Electron vortex is found perpendicular to the magnetic field line and is self‐consist with the peak. We use multipoint spacecraft techniques to determine the propagation velocity of the MP structure and find that the magnetic peak does propagate relative to the plasma (ion) flow. This is very different from the magnetic mirror mode that does not propagate relative to the plasma flow. Furthermore, we developed an efficient method that can effectively distinguish “magnetic bottle like” and “FRs like” structures. The MP presented in this study is identified as magnetic bottle like type. The mechanism to generate the electron scale magnetic bottle like structure is still unclear, suggesting that new theory needs to be developed to understand such small‐scale phenomena.

Section: Summary and Discussionmentioning

confidence: 99%

Section: Summary and Discussionmentioning

confidence: 99%

Magnetospheric Multiscale Observations of Electron Scale Magnetic Peak

Geophysical Research Letters

Shi

Guo

et al. 2018

Self Cite

“…Kinetic-scale magnetic dips (KSMDs) are a significant depression of magnetic field strength with a scale size close to or less than a proton gyroradius (ρ i ). These structures have been observed both in the Earth's magnetospheric plasma sheet (e.g., Ge et al, 2011;Gershman et al, 2016;Goodrich et al, 2016;Sun et al, 2012;Sundberg et al, 2015;Yao et al, 2016;Zhima et al, 2015;Zhang et al, 2017) and magnetosheath (e.g., Yao et al, 2017). In addition to observational investigations, KSMDs have also been extensively studied through theoretical analysis and numerical simulations (e.g., Balikhin et al, 2012;Haynes et al, 2015;Ji et al, 2014;Li et al, 2016;Roytershteyn et al, 2015).…”

Section: Introductionmentioning

confidence: 99%

Waves in Kinetic‐Scale Magnetic Dips: MMS Observations in the Magnetosheath

Shi

Geophysical Research Letters

et al. 2019

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Kinetic‐scale magnetic dips (KSMDs), with a significant depression in magnetic field strength, and scale length close to and less than one proton gyroradius, were reported in the turbulent plasmas both in recent observation and numerical simulation studies. These KSMDs likely play important roles in energy conversion and dissipation. In this study, we present observations of the KSMDs that are labeled whistler mode waves, electrostatic solitary waves, and electron cyclotron waves in the magnetosheath. The observations suggest that electron temperature anisotropy or beams within KSMD structures provide free energy to generate these waves. In addition, the occurrence rates of the waves are higher in the center of the magnetic dips than at their edges, implying that the KSMDs might be the origin of various kinds of waves. We suggest that the KSMDs could provide favorable conditions for the generation of waves and transfer energy to the waves in turbulent magnetosheath plasmas.

“…Previous studies have revealed that the mirror-mode structures are generated in high plasma beta (the ratio of the plasma pressure to the magnetic pressure) regions, with the perpendicular plasma pressure being greater than parallel plasma pressure. They were also often considered a possible source of magnetic dips in many studies (e.g., Ahmadi et al, 2017;Horbury et al, 2004;Joy et al, 2006;Shi et al, 2009;Xiao et al, 2014;Zhang et al, 2008), though different mechanisms were proposed by others (e.g., Balikhin et al, 2012;Ji et al, 2014;Li et al, 2016;Yao et al, 2016Yao et al, , 2017Yao et al, , 2018. Furthermore, their spatiotemporal scales and evolution processes, three-dimensional (3-D) structures, and other important kinetic effects (e.g., drift, finite Larmor radius effect, non-Maxwellian ion distribution, and electron temperature influence) were also extensively investigated (e.g., Ahmadi et al, 2016;Chisham et al, 1998;Feygin et al, 2009;Gary & Karimabadi, 2006;Gedalin et al, 2001;Genot et al, 2009;Hasegawa, 1969;Hellinger et al, 2009;Klimushkin & Chen, 2006;Pokhotelov et al, 2013;Pokhotelov & Pilipenko, 1976;Treumann et al, 2004).…”

Section: Introductionmentioning

confidence: 99%

Electron Dynamics in Magnetosheath Mirror‐Mode Structures

et al. 2018

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Mirror‐mode structures are widely observed in space plasma environments. Although plasma features within the structures have been extensively investigated in theoretical models and numerical simulations, relatively few observational studies have been made, due to a lack of high‐cadence measurements of particle distributions in previous space missions. In this work, electron dynamics associated with mirror‐mode structures are studied based on Magnetospheric Multiscale observations of electron pitch angle distributions. We define mirror‐mode peaks/troughs as the region where the magnetic field strength is greater/smaller than the mean field. The observations show that most electrons are trapped inside the mirror‐mode troughs and display a donut‐like pitch angle distribution configuration. Besides the trapped electrons in mirror‐mode troughs, we find that electrons are also trapped between ambient mirror‐mode peaks and coexisting untrapped electrons within the mirror‐mode structure. Analysis shows that the observed donut‐like electron distributions are the result of betatron cooling and the spatial dependence of electron pitch angles within the structure.