Vlasov simulations of trapping and loss of auroral electrons

Abstract. The plasma on an auroral field line is simulated using a Vlasov model. In the initial state, the acceleration region extends from one to three Earth radii in altitude with about half of the acceleration voltage concentrated in a stationary double layer at the bottom of this region. A population of electrons is trapped between the double layer and their magnetic mirror points at lower altitudes. A simulation study is carried out to examine the effects of fluctuations in the total accelerating voltage, which may be due to changes in the generator or the load of the auroral current circuit. The electron distribution function on the high potential side of the double layer changes significantly depending on whether the perturbation is toward higher or lower voltages, and therefore measurements of electron distribution functions provide information about the recent history of the voltage. Electron phase space holes are seen as a result of the induced fluctuations. Most of the voltage perturbation is assumed by the double layer. Hysteresis effects in the position of the double layer are observed when the voltage first is lowered and then brought back to its initial value.

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Relativistic theory of absorption and emission of electron cyclotron waves in anisotropic plasmas

Journal of Plasma Physics ◽

10.1017/s002237780001285x ◽

1988 ◽

Vol 39 (1) ◽

pp. 61-70 ◽

Cited By ~ 4

Author(s):

A. Orefice

Keyword(s):

Relativistic Theory ◽

Electron Distribution ◽

Electron Distribution Function ◽

Distribution Functions ◽

Electron Cyclotron ◽

Loss Cone ◽

Absorption And Emission ◽

Electron Cyclotron Waves ◽

Plasma Dispersion ◽

Weakly Relativistic Plasma

The weakly relativistic theory of absorption and emission of electron cyclotron waves in hot magnetized plasmas is developed for a large class of anisotropic electron distribution functions. The results are expressed in terms of the weakly relativistic plasma dispersion functions, and therefore of the well-known plasma Z-function. The particular case of a loss-cone electron distribution function is presented as a simple example.

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Coulomb collisions in strongly anisotropic plasmas I. Cyclotron cooling in electron–ion plasmas

Journal of Plasma Physics ◽

10.1017/s0022377820001622 ◽

2021 ◽

Vol 87 (1) ◽

Author(s):

D. Kennedy ◽

P. Helander

Keyword(s):

Electron Distribution ◽

Collision Frequency ◽

Electron Distribution Function ◽

Collision Operator ◽

Distribution Functions ◽

Collision Time ◽

Plasma Parameters ◽

Radiation Emission ◽

Coulomb Collisions ◽

Emission Time

The behaviour of a collisional plasma that is optically thin to cyclotron radiation is considered, and the distribution functions accessible to it on the various time scales in the system are calculated. Particular attention is paid to the limit in which the collision time exceeds the radiation emission time, making the electron distribution function strongly anisotropic. Unusually for plasma physics, the collision operator can nevertheless be calculated analytically although the plasma is far from Maxwellian. The rate of radiation emission is calculated and found to be governed by the collision frequency multiplied by a factor that only depends logarithmically on plasma parameters.

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Some aspects of double layer formation in a plasma constrained by a magnetic mirror

Laser and Particle Beams ◽

10.1017/s0263034600002792 ◽

1987 ◽

Vol 5 (2) ◽

pp. 315-324 ◽

Cited By ~ 2

Author(s):

W. Lennartsson

Keyword(s):

Electric Field ◽

Electric Fields ◽

Double Layer ◽

Large Scale ◽

Scale Effects ◽

Distribution Functions ◽

Electrons And Ions ◽

Auroral Electrons ◽

Complex Electric Field ◽

Necessary And Sufficient

The discussion of parallel electric fields in the earth's magnetosphere has undergone a notable shift of emphasis in recent years, away from wave-generated anomalous resistivity towards the more large-scale effects of magnetic confinement of current carrying plasmas. This shift has been inspired in large part by the more extensive data on auroral particle distribution functions that have been made available, data that may often seem consistent with a dissipation-free acceleration of auroral electrons over an extended altitude range.Efforts to interpret these data have brought new vigor to the concept that a smooth and static electric field can be self-consistently generated by suitable pitch-angle anisotropies among the high-altitude particle populations, different for electrons and ions, and that such an electric field is both necessary and sufficient to maintain the plasma in a quasi-neutral steady state. This paper reviews and criticizes certain aspects of this concept, both from a general theoretical standpoint and from the standpoint of what we know about the magnetospheric environment. It is argued that this concept has flaws and that the actual physical problem is considerably more complicated, requiring a more complex electric field, possibly including double layer structures.

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