Simulations of Dense Planetary Rings: Rotating Self-gravitating particles with size distribution

Details Simulations of Dense Planetary Rings: Rotating Self-gravitating particles with size distribution Simulations of Dense Planetary Rings: Rotating Self-gravitating particles with size distribution

Nov 2004

adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2004dps....36.1901m&link_type=abstract

American Astronomical Society, DPS meeting #36, #19.01; Bulletin of the American Astronomical Society, Vol. 36, p.1109

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Spin state of ring particles is investigated using N-body simulations. Through mutual collisions, some of random kinetic energy is transferred to rotation. For optically thin disks, we confirm that the equilibrium ratio of the rotational energy to the kinetic energy is consistent with the analytic prediction Erot}/E{kin = 2(1-et)/(14-5(1-e_t)), where et represents the tangential restitution coefficient. For optically thick disks, gravitational wakes add large systematic motions to random velocities whereas spin velocities are less enhanced, formally leading to reduced Erot}/E{kin. However, the local random velocities measured by using only the nearest neighbours remain small and the locally measured Erot}/E{kin is in fact larger than the above analytical prediction. In such closely packed systems, spin velocities are enhanced by multiple collisions occurring in same particle pairs with very small time intervals (or one particle hits two other particles alternately). Most importantly, we find that Erot}/E{kin depends quite weakly on particle size for a size distribution case.
Particle spin frequency is one of the important factors determining the temperature difference between lit and unlit faces of Saturn rings, which will be systematically monitored by Cassini space craft. Our results suggest that spin frequencies of largest particles are comparable to the orbital frequency. Since Erot}/E{kin is practically independent of particle radius r, and since the random velocities of the smallest particles are only a few times larger than those of the largest particles, the typical spin frequency is proportional to 1/r. Thus, as long as disk particles possess an extended size distribution, the effective spin frequency (average weighted with particle cross section) is much larger than the orbital frequency. This looks contradictory to the notion of ``slow rotation'' (spin frequency is comparable to the orbital frequency), suggested by previous analyses of thermal infrared observations.

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