48 research outputs found
Polar plasmas as observed by Dynamics Explorers 1 and 2
Plasma measurements from the Dynamics Explorer 1 and 2 satellites were used to characterize the polar cap environment. Analysis of numerous polar-cap passes indicate that, in general, three major regimes of plasma exist: (1) polar rain--electrons with magnetosheath-like energy spectra but much lower densities, most intense near the cusp and weakening toward the central polar cap; (2) polar wind--low energy upward flowing ions with both field-aligned and conical distributions; and (3) acceleration events--sporadic events consistent with the acceleration of electrons and positive ions by parallel electric fields. (1) to (3) were observed at high altitudes by Dynamics Explorer 1, while (1) and (3) were also observed at low altitudes by Dynamics Explorer 2. The plasma parameters associated with these plasma regimes are presented and discussed in terms of source and acceleration mechanisms
Reflection of the strahl within the foot of the Earth's bow shock
The reflection of a fraction of the solar wind at the bow shock to some
extent defines the physical properties of what is known as the foreshock, the
region where the interplanetary magnetic field has a direct connection to the
bow shock. Both ion and electron reflection have been observed and together
form a significant source of free energy that is responsible for many of the
instabilities observed in this region. In this paper we concentrate on the
reflection of electrons at the shock and report two significant findings: the
first is that the strahl, the field-aligned component of the electron solar
wind distribution, appears to be fully reflected at the bow shock; the second
finding is that the reflection is observed to occur in the foot of the shock
and not in the shock ramp. This latter observation implies that mirroring in
these examples is not the primary determinant of the electron reflection
process.</p
Observations of Electron Vorticity in the Inner Plasma Sheet
From a limited number of observations it appears that vorticity is a common feature in the inner plasma sheet. With the four Cluster spacecraft and the four PEACE instruments positioned in a tetrahedral configuration, for the first time it is possible to directly estimate the electron fluid vorticity in a space plasma. We show examples of electron fluid vorticity from multiple plasma sheet crossings. These include three time periods when Cluster passed through a reconnection ion diffusion region. Enhancements in vorticity are seen in association with each crossing of the ion diffusion region
Whistler Waves Driven by Anisotropic Strahl Velocity Distributions: Cluster Observations
Observed properties of the strahl using high resolution 3D electron velocity distribution data obtained from the Cluster/PEACE experiment are used to investigate its linear stability. An automated method to isolate the strahl is used to allow its moments to be computed independent of the solar wind core+halo. Results show that the strahl can have a high temperature anisotropy (T(perpindicular)/T(parallell) approximately > 2). This anisotropy is shown to be an important free energy source for the excitation of high frequency whistler waves. The analysis suggests that the resultant whistler waves are strong enough to regulate the electron velocity distributions in the solar wind through pitch-angle scatterin
First measurements of electron vorticity in the foreshock and solar wind
We describe the methodology used to set up and compute spatial derivatives
of the electron moments using data acquired by the Plasma
Electron And Current Experiment
(PEACE) from the four Cluster spacecraft. The results are used to
investigate electron vorticity in the foreshock. We find that much
of the measured vorticity, under nominal conditions, appears to be
caused by changes in the flow direction of the return (either reflected
or leakage from the magnetosheath) and strahl electron populations
as they couple to changes in the magnetic field orientation. This
in turn results in deflections in the total bulk velocity producing
the measured vorticity
Satellite particle collection during active states of the Tethered Satellite System (TSS)
Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/76723/1/AIAA-1996-2298-205.pd
A possible SAR arc energization source: Precipitating electrons
Coincident measurements by ground-based photometers and satellite-borne electron sensors have shown the association of precipitating electrons and Stable Auroral Red Arcs at mid-latitudes. Modeling of these events has suggested that, within the constraints imposed by uncertainties of the electron energy spectrum, the electron influx carries sufficient energy to establish ionospheric temperatures required to power the arcs.Peer Reviewedhttp://deepblue.lib.umich.edu/bitstream/2027.42/26356/1/0000443.pd