Extreme Ultraviolet Observations from Voyager 1 Encounter with Saturn

Broadfoot, A. L.; Sandel, B. R.; Shemansky, D. E.; Holberg, J. B.; Smith, Gerald R.; Strobel, D. F.; McConnell, J. C.; Kumar, Shailendra; Hunten, D. M.; Atreya, S. K.; Donahue, T. M.; Moos, H. W.; Bertaux, Jean-Loup; Blamont, J. É.; Pomphrey, R. B.; Linick, S.

doi:10.1126/science.212.4491.206

Cited by 409 publications

(188 citation statements)

References 33 publications

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“…The total density increases to a maximum of 2.8 x 1013 mol./cm 2 above the outer A ring for the upper limit on the source and is -2.8 × 1012 mol./cm 3 for one-tenth the source. These are comparable to the total neutral H abundance -1013/cm 2 (Broadfoot et al 1981). The total column density for the energy spectrum of Eq.…”

Section: Ring Cloud: Calculationsmentioning

confidence: 52%

Micrometeorite erosion of the main rings as a source of plasma in the inner Saturnian plasma torus

Pospieszalska

Johnson

1991

Icarus

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Section: Ring Cloud: Calculationsmentioning

confidence: 52%

Micrometeorite erosion of the main rings as a source of plasma in the inner Saturnian plasma torus

Pospieszalska

Johnson

1991

Icarus

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“…Hydrogen atoms (H) emit Lyman alpha radiation (because of resonance scattering of sunlight) which can be detected by ultraviolet spectrometer (UVS) instruments. The Voyager UVS experiments detected H radiation; the original data interpretation was of a torus of H with density of about 20 atoms cm -3 in the vicinity of Titan's orbit [Broadfoot et al, 1981;Sandel et al, 1982]. Subsequent analysis of additional UVS spectra suggests that the H cloud probably has two components, one associated with Titan which is azimuthally asymmetric and centered on Titan's orbit and one which extends in to Saturn's surface which has an intensity peak on the duskside of Saturn [Shemansky and Hall, 1992] (although there is a discrepancy between preencounter and postencounter data as to whether the observations are brightest on the duskside or dawnside).…”

Section: Neutralsmentioning

confidence: 99%

Thermal plasma and neutral gas in Saturn's magnetosphere

Richardson¹

1998

Reviews of Geophysics

121

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Abstract. Saturn's magnetosphere contains plasma and neutral particles from Saturn's atmosphere, the rings, the inner icy satellites, and Titan. This paper reviews the observations of plasma and neutrals near Saturn. Plasma conditions were observed during the Pioneer 11 and Voyager 1 and 2 flybys of Saturn. Neutral H was observed by the Voyagers; neutral OH has been observed by the Hubble Space Telescope. The attempts which have been made to understand the physical processes behind the data are also discussed. Saturn's magnetosphere is dominated by neutrals, with a neutral to plasma density ratio of about 10. The neutrals are probably produced by bombardment of the moons by micrometeorites and heavy ions, although there is a discrepancy between predicted sputtering rates and the amount of sputtering necessary to produce the observed neutral densities. Transport of plasma out of the magnetosphere must be very fast, of the order of a few days. Models of the processes occurring in Saturn's magnetosphere are used to determine the densities of neutral and plasma species which cannot be directly observed. What happens to this plasma? The largest portion recombines back into neutral atoms and goes flying out of the magnetosphere. A significant fraction is transported to the boundary of the magnetosphere and escapes down the magnetotail into the solar wind. Of the rest, some smashes into the rings and moons, knocking off neutrals which then form more plasma, and some enters Titan's and Saturn's atmospheres, providing an energy source to drive atmospheric processes and auroral displays.Most of our knowledge of Saturn's magnetosphere comes from the brief flyby encounters of Pioneer 11 (1979) and Voyager 1 (1980) and 2 (1981). Recent observation• using the Hubble space telescope (HST) also give valuable clues as to the neutral density structure. This paper describes the observations from Saturn's magnetosphere, the current understanding of the

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“…It orbits Saturn at a distance of just over 20 Saturn radii (R S ). Moreover, it is the only satellite with an appreciable atmosphere, one which is composed mostly of nitrogen with some methane and H 2 [see, e.g., Broadfoot et al, 1981]. Titan's interaction with Saturn's magnetosphere was first observed by Voyager 1, Hartle et al [1982] and Neubauer et al [1984] have given the most comprehensive analysis of the Titan interaction based on Voyager 1 data.…”

Section: Introductionmentioning

confidence: 99%

The global plasma environment of Titan as observed by Cassini Plasma Spectrometer during the first two close encounters with Titan

Szegö¹

2005

Geophysical Research Letters

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The Cassini spacecraft flew by Titan on October 26, 2004 and December 13, 2004. In both cases it entered the ionosphere of Titan, allowing exploration of its plasma environment. Using observations from the Cassini Plasma Spectrometer (CAPS) and the Cassini magnetometer along the inbound legs of both flybys, we examine Titan's global plasma environment. On both occasions CAPS detected plasma populations distinct from those of the Kronian magnetosphere at about 1–1.5 Saturn radii from the moon. Closer to Titan CAPS observed drifting ion ring distributions originating from Titan and, in addition, a corotating flow that was significantly decelerated around the moon due to mass loading. Near the moon, but above the ionosphere, very cold plasma was dominant. We also compare the CAPS data to those of Voyager 1.

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Extreme Ultraviolet Observations from Voyager 1 Encounter with Saturn

Cited by 409 publications

References 33 publications

Micrometeorite erosion of the main rings as a source of plasma in the inner Saturnian plasma torus

Micrometeorite erosion of the main rings as a source of plasma in the inner Saturnian plasma torus

Thermal plasma and neutral gas in Saturn's magnetosphere

The global plasma environment of Titan as observed by Cassini Plasma Spectrometer during the first two close encounters with Titan

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