Convection in the Magnetosphere of Saturn During the Cassini Mission Derived From MIMI INCA and CHEMS Measurements

An extensive analysis of Cassini Ion and Neutral Camera (INCA) and Charge Energy Mass Spectrometer (CHEMS) measurements of ~6–231 keV ion anisotropies acquired during selected spin and stare periods for nearly all mission orbits has been completed. Based on this analysis, we find that the computed a...

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Bibliographic Details
Published in:Journal of geophysical research. Space physics 2020-02, Vol.125 (2), p.n/a
Main Authors: Kane, M., Mitchell, D. G., Carbary, J. F., Dialynas, K., Hill, M. E., Krimigis, S. M.
Format: Article
Language:English
Subjects:
Boundary layers
Cassini mission
Convection
Corotation
Hydrogen
Jupiter
Magnetopause
Magnetotails
Mass spectrometry
Oxygen
Planetary magnetospheres
Plasma
Plasma convection
Saturn
Saturn magnetosphere
Time dependence
Titan
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Summary:An extensive analysis of Cassini Ion and Neutral Camera (INCA) and Charge Energy Mass Spectrometer (CHEMS) measurements of ~6–231 keV ion anisotropies acquired during selected spin and stare periods for nearly all mission orbits has been completed. Based on this analysis, we find that the computed azimuthal speed of Saturn's magnetodisk plasma increases within the inner and middle magnetosphere. Beyond the orbit of Titan, in the magnetotail, the calculated rotation speed remains roughly constant with increasing distance from Saturn. The component of convection parallel to Saturn's spin axis is smaller and on average nearly zero. The radial speed of plasma shows distinct local time dependence and increases outward with increasing distance down the magnetotail. The magnetodisk flow remains primarily azimuthal to large distances, indicating the plasma is still under the influence of Saturn as it transits across the nightside. Tailward flows have been observed in the region near the dawn and dusk magnetotail flanks. The plasma flow in the predawn quadrant is much more disorganized than that in the premidnight quadrant. The hydrogen and oxygen hot ion temperatures increase with decreasing distance to Saturn. Some plasma evidently escapes into a dusk boundary layer at the dusk magnetotail flank, while the remaining plasma primarily moves across the magnetotail and is entrained into the flow of a boundary layer at the dawn flank of the magnetotail. When scaled to the magnetopause standoff distance and corotation fraction, the convection speed of plasma in the magnetospheres of Jupiter and Saturn is similarly organized. Key Points Saturn's magnetospheric convection pattern has been extracted from Cassini data The escape of plasma from the system occurs primarily at the magnetotail flanks The magnetotail convection pattern contains a strong dawn‐dusk asymmetry
ISSN:2169-9380
2169-9402
DOI:10.1029/2019JA027534