Electron mirror branch: observational evidence from “historical” AMPTE-IRM and Equator-S measurements

Treumann, R. A.; Baumjohann, W.

doi:10.5194/angeo-36-1563-2018

Cited by 12 publications

(13 citation statements)

References 55 publications

(79 reference statements)

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“…Because generation of whistler mode waves in electron scale magnetic dips has been reported recently (Huang et al, 2018; Yao et al, 2019), if any further electron scale magnetic dips exist, they may be expected to make small scale whistler mode waves. In addition, the existence of electron mirror mode structures in (ion) mirror mode structures was reported by Treumann and Baumjohann (2018), although it has not been expected because of the much lower growth rate compared with that of whistler mode waves which requires the same type of electron anisotropy ( T ⊥e > T ||e ) for wave growth (Ahmadi et al, 2016; Gary & Karimabadi, 2006). Since the wave number of electron mirror mode structures transverse to B is expected to be much larger than that of (ion) mirror mode structures (Noreen et al, 2017), we expect the generation of electron scale fluctuations in the whistler mode wave source regions, if electron mirror structures exist.…”

Section: Discussionmentioning

confidence: 94%

Observations of the Source Region of Whistler Mode Waves in Magnetosheath Mirror Structures

et al. 2020

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In the magnetosheath, intense whistler mode waves, called "Lion roars," are often detected in troughs of magnetic field intensity in mirror mode structures. Using data obtained by the four Magnetospheric Multiscale (MMS) spacecraft, we show that reversals of gradient of magnetic field intensity along the magnetic field correspond to reversals of the field-aligned component of Poynting flux of whistler mode waves in the troughs. Such a characteristic is consistent with the idea that the whistler mode waves are effectively generated near the local minima of magnetic field intensity because of the smallest cyclotron resonance velocity and propagate toward regions of larger magnetic field intensity along the magnetic field lines on both sides. We use the reversal of the Poynting flux as an indicator of wave source regions. In these regions, we find that pancake or an outer edge of butterfly electron distributions above~100 eV are good candidates for wave generation. Unclear correlations of phase difference and amplitude variations of whistler mode waves in cases of~40 km spacecraft separation indicate that a simple plane wave approximation with a constant amplitude is not valid at this spatial scale that is much smaller than the ion gyroradius. The whistler mode waves consist of small coherent wave packets from multiple sources with spatial scales smaller than tens of electron gyroradii transverse to the background magnetic field in a mirror mode structure.

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Section: Discussionmentioning

confidence: 94%

Observations of the Source Region of Whistler Mode Waves in Magnetosheath Mirror Structures

et al. 2020

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“…Their study shows that although the linear growth rate of the electron mirror mode can be much higher than that of the proton mirror mode, the dynamic importance of the electron mirror mode is insignificant since their influence on magnetic field and particle temperature is negligible. Treumann & Baumjohann (2018) suggested that the quasilinear theory as a saturation mechanism does not apply to the mirror mode in space since the observed amplitudes exceed those predicted by quasilinear theory. Their study using old spacecraft data is motivational for future investigations using the high temporal and spatial resolution data set of the MMS mission.…”

Section: Summary and Discussionmentioning

confidence: 98%

“…But so far there have been few unambiguous observations of their existence because the capability to resolve electron-scale structures has been strongly limited by the insufficient measurement resolution of satellite-borne instrumentation. Using magnetic field data obtained from the spacecraft AMPTE-IRM and Equator-S, Treumann & Baumjohann (2018) presented observational evidence for the electron mirror mode in the Earthʼs magnetosheath. Lowfrequency whistler waves were also observed and were used to diagnose the effect of anisotropic electron temperature on the mirror mode.…”

Section: Introductionmentioning

confidence: 99%

Electron Mirror-mode Structure: Magnetospheric Multiscale Observations

Yao

Shi

Yao

et al. 2019

ApJL

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The small-scale mirror mode excited by electron dynamics is a fundamental physical process, attracting research interest in space, laboratory, and astrophysical plasma physics over the past half century. However, the investigations of this process were mostly limited to theories and numerical simulations, with no direct observational evidence for their existence. In this study we present clear observations of electron mirror-mode using Magnetospheric Multiscale data at unprecedented high temporal cadence. These structures are train-like, compressible, nonpropagating, and satisfy the theoretical excitation and electron trapping conditions. They were observed near the Earthʼs foreshock and its downstream turbulence during the corotating interaction region events, which could be involved with the interaction between solar wind and Earth.

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“…One way out of the above mentioned basic physical dilemma between observation and theory may be related to the resonance of bouncing particles in the mirror bubble and the persistent thermal ion-acoustic background noise which is independent of the presence of mirror modes (Rodriguez and Gurnett, 1975;Treumann and Baumjohann, 2018a;Treumann and Baumjohann, 2019). These resonant bouncing particles (we here restrict to electrons, but ions if bouncing could contribute in a similar way as well) form the required condensate for phase transition.…”

Section: Quasi-superconducting Phase Transitionmentioning

confidence: 99%

“…Landau diamagnetic theory (cf., e.g., Huang, 1973) suggests that any finite temperature diamagnetism is macroscopically very small, which is confirmed by simulations (Noreen et al, 2017) which show the saturation amplitude to remain minuscule. The observation of large-amplitude localized quasi-stationary magnetic depletions of (50% (see Treumann and Baumjohann, 2018a, for examples, in high resolution) must be enforced by conditions which are not included in linear or quasilinear theory (Treumann et al, 2004). We do not go into discussing this problem here as it has been the subject of previous publications (cf., Treumann and Baumjohann, 2018b;Treumann and Baumjohann, 2019).…”

Section: Introductionmentioning

confidence: 99%

Mirror Mode Junctions as Sources of Radiation

Treumann

Baumjohann

2021

Front. Astron. Space Sci.

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Mirror modes in collisionless high-temperature plasmas represent macroscopic high-temperature quasi-superconductors with bouncing electrons in discrete-particle resonance with thermal ion-sound noise contributing to the ion-mode growth beyond quasilinear stability. In the semi-classical Ginzburg-Landau approximation the conditions for phase transition are reviewed. The quasi-superconducting state is of second kind causing a magnetically perforated plasma texture. Focussing on the interaction of mirror bubbles we apply semi-classical Josephson conditions and show that a mirror perforated plasma emits weak electromagnetic radiation which in the magnetosheath should be in the sub-millimeter, respectively, infrared range. This effect might be of astrophysical importance.

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Electron mirror branch: observational evidence from “historical” AMPTE-IRM and Equator-S measurements

Cited by 12 publications

References 55 publications

Observations of the Source Region of Whistler Mode Waves in Magnetosheath Mirror Structures

Observations of the Source Region of Whistler Mode Waves in Magnetosheath Mirror Structures

Electron Mirror-mode Structure: Magnetospheric Multiscale Observations

Mirror Mode Junctions as Sources of Radiation

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