Corrugations and eccentric spirals in Saturn's D ring: New insights into what happened at Saturn in 1983

TL;DR

This study uses Cassini data to analyze vertical corrugations and eccentric patterns in Saturn's D ring, revealing insights into a 1983 impact event that tilted the ring and disturbed particle motions.

Contribution

It provides detailed analysis of ring corrugations and eccentricities, suggesting a steep impact angle and timing differences indicating debris origin from a breakup near Saturn.

Findings

Vertical motions were 2.3 times larger than in-plane motions.

Corrugation wavelengths are about 0.7% shorter than expected.

Timing suggests debris impact occurred about 60 days before the C ring disturbance.

Abstract

Previous investigations of Saturn's outer D ring (73,200-74,000 km from Saturn's center) identified periodic brightness variations whose radial wavenumber increased linearly over time. This pattern was attributed to a vertical corrugation, and its temporal variability implied that some event --possibly an impact with interplanetary debris-- caused the ring to become tilted out the planet's equatorial plane in 1983. This work examines these patterns in greater detail using a more extensive set of Cassini images in order to obtain additional insights into the 1983 event. These additional data reveal that the D ring is not only corrugated, but also contains a time-variable periodic modulation in its optical depth that probably represents organized eccentric motions of the D-ring's particles. This second pattern suggests that whatever event tilted the rings also disturbed the radial or azimuthal velocities of the ring particles. Furthermore, the relative amplitudes of the two patterns indicate that the vertical motions induced by the 1983 event were 2.3+/-0.5 times larger than the corresponding in-plane motions. If these structures were indeed produced by an impact, material would need to strike the ring at a steep angle (more than 60 degrees from the ring plane) to produce such motions. Meanwhile, the corrugation wavelengths in the D ring are about 0.7% shorter than one would predict based on extrapolations from similar structures in the nearby C ring. This could indicate that the D-ring was tilted/disturbed about 60 days before the C ring. Such a timing difference could be explained if the material that struck the ring was derived from debris released when some object broke up near Saturn some months earlier. This debris would need to have a substantial initial velocity dispersion and have its orbital properties perturbed by solar tides prior to its collision with the rings.