2 results
8 - Moonlets in Dense Planetary Rings
- from III - Ring Systems by Type and Topic
-
- By F. Spahn, University of Potsdam Potsdam, GERMANY, H. Hoffmann, University of Potsdam Potsdam, GERMANY, H. Rein, University of Toronto Toronto, Ontario, CANADA, M. Seiss, University of Potsdam Potsdam, GERMANY, M. Sremčević, University of Colorado Boulder, Colorado, USA, M.S. Tiscareno, SETI Institute Mountain View, California, USA
- Edited by Matthew S. Tiscareno, Carl D. Murray, Queen Mary University of London
-
- Book:
- Planetary Ring Systems
- Published online:
- 26 February 2018
- Print publication:
- 22 March 2018, pp 157-197
-
- Chapter
- Export citation
-
Summary
INTRODUCTION
When, in 1610, Galileo Galilei directed his telescope at Saturn, he discovered some puzzling addenda on either side of that planet, changing their appearance over the course of a few years – and even more disturbing, at certain instants they seemed to disappear and then return. These appendages remained a scientific riddle for about half a century until Christian Huygens came up with a seemingly correct model – he proposed that a solid ring is girdling Saturn. In 1675, G. D. Cassini's detection of a division in Saturn's rings – the Cassini Division separating the outer A and inner B rings – questioned Huygens’ hypothesis of a solid ring.
Almost 200 years later, in his famous work, Maxwell (1859) proved that a solid ring cannot be a stable configuration, suggesting instead that a myriad of individual tiny satellites form the rings of Saturn. This theoretical prediction was later confirmed experimentally by J. E. Keeler, who measured Doppler frequency shifts on either side of Saturn's rings (Keeler, 1889, 1895), showing that individual ring particles encircle Saturn at Kepler speeds.
Since those studies in the nineteenth century, the mesoscopic particulate nature of Saturn's rings has been widely accepted. Since the prediction of a flat monolayer ring by Jeffreys (1947), mainly suggested by the frequent inelastic collisions among the ring particles, only a little has been said about the properties of ring particles themselves – their size distribution, composition, etc., and their evolution as a granular ensemble.
Hénon (1981), motivated by the Pioneer and Voyager space missions to the outer solar system in the late 1970s and early 1980s, assumed a broad size distribution of the ring particles in order to explain spacecraft observations of the dense rings of Saturn. Properties like the apparent thickness of the rings or the distribution of the widths of dilute or empty gaps have been addressed by an extended power-law to characterize the size distribution of the ring particles. The idea behind this approach is that, depending on its size, a ring particle (especially sub-kilometer or kilometer-sized boulders, hereafter called moonlets) should gravitationally carve density features in the surrounding ring matter.
Hydrodynamics of Saturn’s Dense Rings
- M. Seiß, F. Spahn
-
- Journal:
- Mathematical Modelling of Natural Phenomena / Volume 6 / Issue 4 / 2011
- Published online by Cambridge University Press:
- 18 July 2011, pp. 191-218
- Print publication:
- 2011
-
- Article
- Export citation
-
The space missions Voyager and Cassini together with earthbound observations revealed a wealth of structures in Saturn’s rings. There are, for example, waves being excited at ring positions which are in orbital resonance with Saturn’s moons. Other structures can be assigned to embedded moons like empty gaps, moon induced wakes or S-shaped propeller features. Furthermore, irregular radial structures are observed in the range from 10 meters until kilometers. Here some of these structures will be discussed in the frame of hydrodynamical modeling of Saturn’s dense rings. For this purpose we will characterize the physical properties of the ring particle ensemble by mean field quantities and point to the special behavior of the transport coefficients. We show that unperturbed rings can become unstable and how diffusion acts in the rings. Additionally, the alternative streamline formalism is introduced to describe perturbed regions of dense rings with applications to the wake damping and the dispersion relation of the density waves.