Temps-Espace-Société
Ring formation around giant planets by tidal disruption
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DENISSE (PARIS)
DENISSE
PARIS
Description
Planetary rings are ubiquitous structure in our Solar System, but their formation mechanisms remain under debate. One of the proposed scenarios is the tidal disruption of a nearby passing body that enters within a planet Roche limit, producing fragments that are gravitationally captured and finally form the rings. In this study, we investigate the detailed dynamical path and fate of such tidally captured fragments using direct N-body simulations including collisional fragmentation with analytical arguments. Focusing on Saturn as a representative case, we explore how the inclination (i_TD) and pericenter distance (q_TD) of the orbit of the passing body control the subsequent orbital evolution, collisional grinding, and the survival of fragments mass. Our simulations show that initially highly eccentric and inclined fragments experience differential precession driven by the planet J2 potential, followed by destructive high-velocity collisions that damp their eccentricities and inclinations. The timing and pathway of this evolution strongly depend on i_TD, modifying the dynamical picture proposed in the previous work. For low to moderate i_TD, a narrow, circular and equatorial rings finally form whose orbital radius is well predicted by an analytically derived equivalent circular radius based on the conservation of the vertical component of angular momentum. In contrast, for high i_TD, collisional damping causes a substantial fraction of the material to fall onto the planet, preventing the formation of a massive ring. We compile our results of N-body simulations with the analytical predictions on (q_TD, i_TD) parameter space and specify the parameter region where sufficient mass to form Saturn's present rings and inner satellites survives. Our results provide a unified dynamical framework linking tidal disruption events, ring formation, and the initial conditions for ring's satellite system evolution, which are also readily applied to the other giant and terrestrial planets.
https://cnrs.zoom.us/j/91889862989?pwd=KJOv4F2nl177y09GxPM5JBbWdERJci.1