Evidence for dust-driven, radial plasma transport in Saturn’s inner radiation belts
•First time detection of signatures from Saturn’s faint rings in energetic ion data.•No detection of additional moons or rings inside Enceladus, besides the known ones.•Faint-ring driven electron losses significantly displaced from the ring locations.•Plasma transport at Saturn’s radiation belts is...
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Veröffentlicht in: | Icarus (New York, N.Y. 1962) N.Y. 1962), 2016-08, Vol.274, p.272-283 |
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Zusammenfassung: | •First time detection of signatures from Saturn’s faint rings in energetic ion data.•No detection of additional moons or rings inside Enceladus, besides the known ones.•Faint-ring driven electron losses significantly displaced from the ring locations.•Plasma transport at Saturn’s radiation belts is enhanced by dust-driven processes.
A survey of Cassini MIMI/LEMMS data acquired between 2004 and 2015 has led to the identification of 13 energetic electron microsignatures that can be attributed to particle losses on one of the several faint rings of the planet. Most of the signatures were detected near L-shells that map between the orbits of Mimas and Enceladus or near the G-ring. Our analysis indicates that it is very unlikely for these signatures to have originated from absorption on Mimas, Enceladus or unidentified Moons and rings, even though most were not found exactly at the L-shells of the known rings of the saturnian system (G-ring, Methone, Anthe, Pallene). The lack of additional absorbers is apparent in the L-shell distribution of MeV ions which are very sensitive for tracing the location of weakly absorbing material permanently present in Saturn’s radiation belts. This sensitivity is demonstrated by the identification, for the first time, of the proton absorption signatures from the asteroid-sized Moons Pallene, Anthe and/or their rings. For this reason, we investigate the possibility that the 13 energetic electron events formed at known saturnian rings and the resulting depletions were later displaced radially by one or more magnetospheric processes. Our calculations indicate that the displacement magnitude for several of those signatures is much larger than the one that can be attributed to radial flows imposed by the recently discovered noon-to-midnight electric field in Saturn’s inner magnetosphere. This observation is consistent with a mechanism where radial plasma velocities are enhanced near dusty obstacles. Several possibilities are discussed that may explain this observation, including a dust-driven magnetospheric interchange instability, mass loading by the pick-up of nanometer charged dust grains and global magnetospheric electric fields induced by perturbed orbits of charged dust due to the act of solar radiation pressure. Indirect evidence for a global scale interaction between the magnetosphere and Saturn’s faint rings that may drive such radial transport processes may also exist in previously reported measurements of plasma density by |
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ISSN: | 0019-1035 1090-2643 |
DOI: | 10.1016/j.icarus.2016.02.054 |