Magnetotail particle distributions associated with pitch angle isotropization

Abstract Particle drifts perpendicular to the background magnetic field have been proposed by some authors as an explanation for the very efficient perpendicular transport of solar energetic particles (SEPs). This process, however, competes with perpendicular diffusion caused by magnetic turbulence, which can also disrupt the drift patterns and reduce the magnitude of drift effects. The latter phenomenon is well known in cosmic-ray studies, but not yet considered in SEP models. Additionally, SEP models that do not include drifts, especially for electrons, use turbulent drift reduction as a justification of this omission, without critically evaluating or testing this assumption. This article presents the first theoretical step for a theory of drift suppression in SEP transport. This is done by deriving the turbulence-dependent drift reduction function with a pitch-angle dependence, as is applicable for anisotropic particle distributions, and by investigating to what extent drifts will be reduced in the inner heliosphere for realistic turbulence conditions and different pitch-angle dependencies of the perpendicular diffusion coefficient. The influence of the derived turbulent drift reduction factors on the transport of SEPs are tested, using a state-of-the-art SEP transport code, for several expressions of theoretically derived perpendicular diffusion coefficients. It is found, for realistic turbulence conditions in the inner heliosphere, that cross-field diffusion will have the largest influence on the perpendicular transport of SEPs, as opposed to particle drifts.

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Helical Magnetic Cavities: Kinetic Model and Comparison with MMS Observations

10.5194/egusphere-egu21-8905 ◽

2021 ◽

Author(s):

Jinghuan Li ◽

Xuzhi Zhou ◽

Fan Yang ◽

Anton V. Artemyev ◽

Qiugang Zong

Keyword(s):

Magnetic Field ◽

Kinetic Model ◽

Pitch Angle ◽

Maxwell Equations ◽

Equilibrium Solution ◽

Space Plasma ◽

Azimuthal Magnetic Field ◽

Particle Distributions ◽

Multi Scale ◽

Self Consistent

<p>Magnetic cavities are sudden depressions of magnetic field strength widely observed in the space plasma environments, which are often accompanied by plasma density and pressure enhancement. To describe these cavities, a self-consistent kinetic model has been proposed as an equilibrium solution to the Vlasov-Maxwell equations. However, observations from the Magnetospheric Multi-Scale (MMS) constellation have shown the existence of helical magnetic cavities characterized by the presence of azimuthal magnetic field, which could not be reconstructed by the aforementioned model. Here, we take into account another invariant of motion, the canonical axial momentum, to construct the particle distributions and accordingly modify the equilibrium model. The reconstructed magnetic cavity shows excellent agreement with the MMS1 observations not only in the electromagnetic field and plasma moment profiles but also in electron pitch-angle distributions. With the same set of parameters, the model also predicts signatures of the neighboring MMS3 spacecraft, matching its observations satisfactorily.</p>

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Unmagnetized diffusion for azimuthally symmetric wave and particle distributions

Journal of Plasma Physics ◽

10.1017/s0022377800013192 ◽

1988 ◽

Vol 40 (1) ◽

pp. 179-198 ◽

Cited By ~ 5

Author(s):

P. B. Dusenbery ◽

L. R. Lyons

Keyword(s):

Magnetic Field ◽

Diffusion Coefficients ◽

Pitch Angle ◽

Particle Distribution ◽

Ion Beam ◽

Distribution Model ◽

Sound Waves ◽

Linear Diffusion ◽

Particle Distributions ◽

Diffusion Rates

The general equations describing the quasi-linear diffusion of charged particles from resonant interactions with a spectrum of electrostatic waves are given, assuming the wave and particle distributions to be azimuthally symmetric. These equations apply when a magnetic field organizes the wave and particle distributions in space, but when the local interaction between the waves and particles can be evaluated assuming that no magnetic field is present. Such diffusion is, in general, two-dimensional and is similar to magnetized diffusion. The connection between the two types of diffusion is presented. In order to apply the general quasi-linear diffusion coefficients in pitch angle and speed, a specific particle-distribution model is assumed. An expression for the unmagnetized dielectric function is derived and evaluated for the assumed particle distribution model. It is found that slow-mode ion-sound waves are unstable for the range of plasma parameters considered. A qualitative interpretation of unmagnetized diffusion is presented. The diffusion coefficients are then evaluated for resonant ion interactions with ion-sound waves. The results illustrate how resonant ion diffusion rates vary with pitch angle and speed, and how the diffusion rates depend upon the distribution of wave energy in k–space. The results of this study have relevance for ion beam heating in the plasma-sheet boundary layer and upstream of the earth's bow shock.

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On the origin of field-aligned beams at the quasi-perpendicular bow shock: multi-spacecraft observations by Cluster

Annales Geophysicae ◽

10.5194/angeo-22-2301-2004 ◽

2004 ◽

Vol 22 (7) ◽

pp. 2301-2308 ◽

Cited By ~ 42

Author(s):

H. Kucharek ◽

E. Möbius ◽

M. Scholer ◽

C. Mouikis ◽

L. M. Kistler ◽

...

Keyword(s):

Pitch Angle ◽

Temporal Evolution ◽

Ion Beams ◽

Bow Shock ◽

Production Mechanism ◽

Ion Distribution ◽

Low Mach Number ◽

Particle Distributions ◽

Cluster Ion ◽

Basic Production

Abstract. Two distinct populations of reflected and accelerated ions are known to originate from quasi-perpendicular shocks, gyrating ions and reflected ion beams. Recent observations under such bow shock conditions with Cluster have shown strong evidence that both particle distributions appear to emerge from the same reflection process. In this paper the basic production mechanism of field-aligned beams has been investigated by using CLUSTER multi-spacecraft measurements. We have analyzed several quasi-perpendicular shocks with the Cluster Ion Spectrometry experiment (CIS) and followed the spatial and temporal evolution of the reflected and transmitted ion populations across the shock. These observations show that the field-aligned beams most likely result from effective scattering in pitch angle during reflection in the shock ramp. Investigating a low Mach number shock, leakage of a fraction of the thermalized ion distribution in the downstream region does not appear to be the source as the volume in phase space occupied by beam ions is empty downstream of the shock ramp.

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Energetic particle observations at the subsolar magnetopause

Annales Geophysicae ◽

10.5194/angeo-20-445-2002 ◽

2002 ◽

Vol 20 (4) ◽

pp. 445-460 ◽

Cited By ~ 9

Author(s):

A. A. Eccles ◽

T. A. Fritz

Keyword(s):

Pitch Angle ◽

Energetic Particle ◽

Three Dimensional ◽

Extended Period ◽

Energetic Particles ◽

Current Layer ◽

Particle Distributions ◽

Magnetospheric Configuration And Dynamics ◽

Subsolar Point ◽

Magnetospheric Configuration

Abstract. The pitch-angle distributions (PAD) of energetic particles are examined as the ISEE-1 satellite crosses the Earth’s magnetopause near the subsolar point. The investigation focuses on the possible existence of a particular type of distribution that would be associated with a source of energetic particles in the high-latitude magnetosphere. PADs, demonstrating broad, persistent field-aligned fluxes filling a single hemisphere (upper/northern or lower/southern), were observed just sunward of the magnetopause current layer for an extended period of many minutes. These distributions are a direct prediction of a possible source of energetic particles located in the high altitude dayside cusp and we present five examples in detail of the three-dimensional particle distributions to demonstrate their existence. From these results, other possible causes of such PADs are examined.Key words. Magnetospheric physics (energetic particles, precipitating; magnetopause, cusp and boundary layers; magnetospheric configuration and dynamics)

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