The Electron Drift Instrument for MMS

Torbert, R. B.; Vaith, H.; Granoff, M.; Widholm, M.; Gaidos, J. A.; Briggs, B. H.; Dors, I.; Chutter, M.; Macri, J.; Argall, M. R.; Bodet, D.; Needell, J.; Steller, M.; Baumjohann, W.; Nakamura, R.; Plaschke, Ferdinand; Öttacher, H.; Hasiba, J.; Hofmann, K.R.; Kletzing, C. A.; Bounds, S. R.; Dvorský, Richard; Sigsbee, K.; Kooi, V.

doi:10.1007/s11214-015-0182-7

Cited by 56 publications

(42 citation statements)

References 10 publications

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“…The MMS spacecraft has spent a large amount of time in the magnetosheath and has crossed the magnetopause many times to capture the dynamics of the magnetic reconnection (Burch et al, 2015), and it has provided many observations of mirror mode structures in the magnetosheath. One of the unique features of MMS mission is the high time resolution of particle and field measurements when the spacecraft is in burst mode (Baker et al, 2016;Ergun et al, 2016;Fuselier et al, 2016;Le Contel et al, 2014;Lindqvist et al, 2014;Pollock et al, 2016;Russell et al, 2014;Torbert et al, 2016). Using burst mode MMS data, there have been recent studies of whistler waves in the magnetosheath associated with mirror mode structures (Breuillard et al, 2017).…”

Section: Mms Observationsmentioning

confidence: 99%

Generation of Electron Whistler Waves at the Mirror Mode Magnetic Holes: MMS Observations and PIC Simulation

et al. 2018

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The Magnetospheric Multiscale mission has observed electron whistler waves at the center and at the edges of magnetic holes in the dayside magnetosheath. The magnetic holes are nonlinear mirror structures since their magnitude is anticorrelated with particle density. In this article, we examine the growth mechanisms of these whistler waves and their interaction with the host magnetic hole. In the observations, as magnetic holes develop and get deeper, an electron population gets trapped and develops a temperature anisotropy favorable for whistler waves to be generated. In addition, the decrease in magnetic field magnitude and the increase in density reduce the electron resonance energy, which promotes the electron cyclotron resonance. To investigate this process, we used expanding box particle‐in‐cell simulations to produce the mirror instability, which then evolve into magnetic holes. The simulation shows that whistler waves can be generated at the center and edges of magnetic holes, which reproduces the primary features of the MMS observations. The simulation shows that the electron temperature anisotropy develops in the center of the magnetic hole once the mirror instability reaches its nonlinear stage of evolution. The plasma is then unstable to whistler waves at the minimum of the magnetic field structures. In the saturation regime of mirror instability, when magnetic holes are developed, the electron temperature anisotropy appears at the edges of the holes and electron distributions become more isotropic at the magnetic field minimum. At the edges, the expansion of magnetic holes decelerates the electrons, which leads to temperature anisotropies.

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Section: Mms Observationsmentioning

confidence: 99%

Generation of Electron Whistler Waves at the Mirror Mode Magnetic Holes: MMS Observations and PIC Simulation

et al. 2018

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“…Additionally, 65,536 S/s AC-coupled electric field data were used to identify Langmuir oscillations in the vicinity of the whistler waves. Data from the Fast Plasma Instrument (FPI) [Burch et al, 2015], electron drift instrument (EDI) [Torbert et al, 2014], and flux gate magnetometer [Russell et al, 2014] provide context for the waves with respect to the reconnection geometry. We show that the whistler mode waves are confined to the boundary layer and propagate along the magnetosphere-side separatrix of the X line.…”

Section: Introductionmentioning

confidence: 99%

Observations of whistler mode waves with nonlinear parallel electric fields near the dayside magnetic reconnection separatrix by the Magnetospheric Multiscale mission

Wilder

Ergun

Goodrich

et al. 2016

Geophysical Research Letters

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We show observations from the Magnetospheric Multiscale (MMS) mission of whistler mode waves in the Earth's low‐latitude boundary layer (LLBL) during a magnetic reconnection event. The waves propagated obliquely to the magnetic field toward the X line and were confined to the edge of a southward jet in the LLBL. Bipolar parallel electric fields interpreted as electrostatic solitary waves (ESW) are observed intermittently and appear to be in phase with the parallel component of the whistler oscillations. The polarity of the ESWs suggests that if they propagate with the waves, they are electron enhancements as opposed to electron holes. The reduced electron distribution shows a shoulder in the distribution for parallel velocities between 17,000 and 22,000 km/s, which persisted during the interval when ESWs were observed, and is near the phase velocity of the whistlers. This shoulder can drive Langmuir waves, which were observed in the high‐frequency parallel electric field data.

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“…All of the observations presented here are from MMS-4. The Electron Drift Investigation (EDI) [Torbert et al, 2016] operating in the ambient mode (corresponding to an electron energy of 500 eV) is used to measure electron counts to determine the streaming direction of electrons from the reconnection site, i.e., to locate the direction of the reconnection site relative to MMS. Moments of the ion distributions (particularly, the flow velocity in the magnetosheath), plasma composition, and the identification of the boundary layers and magnetopause current layer are from the Hot Plasma Composition Analyzer (HPCA) instrument [Young et al, 2014].…”

Section: Observationsmentioning

confidence: 99%

“…These measurements are also used to determine the pitch angle of particles streaming parallel or antiparallel with respect to the local magnetic field. The Electron Drift Investigation (EDI) [Torbert et al, 2016] operating in the ambient mode (corresponding to an electron energy of 500 eV) is used to measure electron counts to determine the streaming direction of electrons from the reconnection site, i.e., to locate the direction of the reconnection site relative to MMS. Omnidirectional electron flux from the Fast Plasma Investigation Dual Electron Spectrometer (FPI-DES) [Pollock et al, 2016] is also used to identify regions during this encounter with the magnetopause.…”

Section: Observationsmentioning

confidence: 99%

Stable reconnection at the dusk flank magnetopause

Gomez

Vines

Fuselier

et al. 2016

Geophysical Research Letters

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The dusk flank magnetopause was surveyed with instruments on board the Magnetospheric Multiscale (MMS) spacecraft on 28 August 2015 between 13:55 UT and 14:15 UT during a period of persistent southward interplanetary magnetic field (IMF) with varying dawn‐dusk component. Plasma measurements (500 eV electrons, > 2 keV ions) revealed the existence of at least one active reconnection region that persisted throughout the interval. The reconnection region convected equatorward despite the poleward and tailward magnetosheath flow, which ranged from slightly sub‐Alfvénic to slightly super‐Alfvénic throughout the interval. These results suggest that magnetic reconnection moved in response to changes in the IMF clock angle rather than the magnetosheath flow, which is corroborated using predictions of the maximum magnetic shear model.

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The Electron Drift Instrument for MMS

Cited by 56 publications

References 10 publications

Generation of Electron Whistler Waves at the Mirror Mode Magnetic Holes: MMS Observations and PIC Simulation

Generation of Electron Whistler Waves at the Mirror Mode Magnetic Holes: MMS Observations and PIC Simulation

Observations of whistler mode waves with nonlinear parallel electric fields near the dayside magnetic reconnection separatrix by the Magnetospheric Multiscale mission

Stable reconnection at the dusk flank magnetopause

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