Characteristics of Solitary Waves and Weak Double Layers in the Magnetospheric Plasma

Boström, R.; Gustafsson, G.; Holback, B.; Holmgren, Gunnar; Koskinen, Hannu E. J.; Kintner, P. M.

doi:10.1103/physrevlett.61.82

Cited by 441 publications

(226 citation statements)

References 19 publications

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“…This result was based upon Langmuir probe sweeps near the ion beams which inferred a 1-10 eV temperature for the electrons [Bostrom et at., 1988]. However, Hilgers et al [1992] show that the Viking Langmuir probe current is dominated by photoelectrons from the wire boom within ion beam regions.…”

Section: Observationsmentioning

confidence: 99%

“…No mass separation was performed and the cold ions were assumed to be hydrogen. A cold electron (few eV) component with roughly the same density, as required for charge neutrality, was inferred from Langmuir probe measurements [Bostrom et at., 1988; Koskinen et at., 1989]. These Viking observations were made at 8000-11000 km altitudes, in the afternoon-evening sector and in a region whose total accelerating potential was about 1 kV.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Ion and electron characteristics in auroral density cavities associated with ion beams: No evidence for cold ionospheric plasma

McFadden¹,

Carlson²,

Ergun³

et al. 1999

J. Geophys. Res.

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Abstract. Low-density cavities associated with upgoing ion beams were identified in the auroral regions over two decades ago. In order to understand the waves, double layers, and solitary structures observed within these cavities, accurate measurements of the plasma distribution function are required. Although measurements by DE 1 indicated that these cavities were composed primarily of hot plasma in the form of ion beams, plasma sheet ions, and inverted V electrons, later reports from Viking showed these cavities contained a cold plasma component whose density was an order of magnitude larger than the hot component. Recent measurements by the FAST satellite contrast sharply with the Viking results and support the earlier DE 1 observations. Regions of upgoing ion beams observed by FAST are shown to contain little or no cold plasma. The hot electron densities (> 100 eV) and the combined plasma sheet ion and upgoing ion beam densities (>30 eV) agree remarkably well. Furthermore, no cold ions (0-30 eV) are measured at low energies by the mass spectrometer, which precludes the presence of significant (>20%) cold electrons to preserve charge neutrality. Characteristics of the plasma for 11 ion beam events are tabulated.

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Section: Observationsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Ion and electron characteristics in auroral density cavities associated with ion beams: No evidence for cold ionospheric plasma

McFadden¹,

Carlson²,

Ergun³

et al. 1999

J. Geophys. Res.

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“…Satellite measurements of the high-frequency electric field have revealed the existence of electrostatic ion-cyclotron waves (EICW) and of solitary waves, also named double layers (DL), in which the potential can jump parallel to B by a good fraction of kT e over scales of the order of 10 Debye lengths, X D (Temerin et al 1982;Bostrom et al 1988). The postulated anomalous resistivity may thus be distributed (EICW) or concentrated in a multitude of small ion-acoustic double layers (DL).…”

Section: Microphysicsmentioning

confidence: 99%

Acceleration from Field-Aligned Potential Drops

Haerendel

1994

International Astronomical Union Colloquium

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Unstable field-aligned currents are seen as the origin of field-aligned potential drops. They convert energy stored in magnetic shear stresses into kinetic energy. A good fraction of this energy is carried by runaway electrons and ions out of the acceleration region. The paper emphasizes the analogy with mechanical fractures. Simple expressions for the energy conversion rate and the parallel potential drop are derived, the two being linked by the critical current density needed for instability. The origin of the currents (generator) lies mostly in a region remote from that of energy conversion (fracture zone). The transmission of shear stresses and energy from the generator plasma, where the primary forces are applied to the fracture zone is also considered. A closed set of relations allows quantitative evaluation of the energetic particle production efficiency. The decoupling of the plasma on either side of the fracture zone which allows fast stress relief is described in detail, as well as a stationary model for the Alfven wave interaction between fracture zone and generator plasma. A simple concept of the nature of the anomalous resistivity generated by the unstable current leads to an expression for the magnetic diffusivity inside the fracture zone and an estimate of the latter's extent parallel to the magnetic field, whereas its width and length transverse to B follow from the macroscopic relations. Finally and as an example, the theory is applied to the problem of fast electron (and ion) acceleration well above 1 MeV seen to occur in many solar flares. It is obvious that this process belongs to the most powerful production processes of high-energy particles in stellar magnetic fields.

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“…Other evidences of accelerated electrons, with broader distributions in energy and direction, have shown the importance of time-varying electric fields [Hultqvist et al, 1988], possibly carried by Alfvén waves [Kletzing, 1994]. Deep plasma cavities above the Earth auroral zone are a privileged place for electron acceleration [Hilgers et al, 1992] and the subsequent turbulence, characterized by electrostatic coherent structures such as double layers and solitary waves [Bostrom et al, 1988;Eriksson et al, 1997]. With the Freja spacecraft, is was shown that these regions are pervaded by Alfvén wave packets (termed as Solitary Kinetic Alfvén Waves, SKAW).…”

Section: Introductionmentioning

confidence: 99%

Electron acceleration by an Alfvénic pulse propagating in an auroral plasma cavity

Mottez

Génot

2011

J. Geophys. Res.

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[1] With the help of a 2.5-D particle-in-cell simulation code, we investigate the physics of the acceleration of auroral electrons, through the interaction of an isolated Alfvén wave packet with a plasma density cavity. The cavity is edged by density gradients perpendicular to the magnetic field. We show that a single passing of an isolated wave packet over a (infinite) cavity creates an electron beam. It triggers local current and beam-plasma instabilities and small-scale coherent electric structures. The energy flux of downgoing electrons is significantly increased, whereas upgoing electrons are also accelerated, even if no beam is formed. Accelerated electrons remain after the passage of the Alfvénic pulse, allowing the observation of energetic particles without any significant electromagnetic perturbation. The dependence of this process on the electron to ion mass ratio is consistent with its control by inertial effects.Citation: Mottez, F., and V. Génot (2011), Electron acceleration by an Alfvénic pulse propagating in an auroral plasma cavity, J. Geophys. Res., 116,

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Characteristics of Solitary Waves and Weak Double Layers in the Magnetospheric Plasma

Cited by 441 publications

References 19 publications

Ion and electron characteristics in auroral density cavities associated with ion beams: No evidence for cold ionospheric plasma

Ion and electron characteristics in auroral density cavities associated with ion beams: No evidence for cold ionospheric plasma

Acceleration from Field-Aligned Potential Drops

Electron acceleration by an Alfvénic pulse propagating in an auroral plasma cavity

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