Viscous Overstability in Saturn's Rings: Influence of Collective Self-gravity

TL;DR

This study explores how collective self-gravity influences the nonlinear evolution of viscous overstability in Saturn's rings, using hydrodynamic models and N-body simulations to match observed micro-structures.

Contribution

It introduces a combined hydrodynamic and N-body approach to analyze the impact of self-gravity on overstability wavelengths in Saturn's rings, extending previous models.

Findings

Self-gravity shifts overstability wavelengths to near the dispersion relation's frequency minimum.

Hydrodynamic and N-body models agree well for moderate to strong self-gravity.

Wavelengths of 100-300m match Cassini observations of ring micro-structures.

Abstract

We investigate the influence of collective self-gravity forces on the nonlinear, large-scale evolution of the viscous overstability in Saturn's rings. We numerically solve the axisymmetric hydrodynamic equations in the isothermal and non-isothermal approximation, including radial self-gravity and employing transport coefficients derived by Salo et al. We assume optical depths of 1.5-2 to model Saturn's dense rings. Furthermore, local N-body simulations, incorporating vertical and radial collective self-gravity are performed. Vertical self-gravity is mimicked through an increased frequency of vertical oscillations, while radial self-gravity is approximated by solving the Poisson equation for an axisymmetric thin disk with a Fourier method. Direct particle-particle forces are omitted, which prevents small-scale gravitational instabilities (self-gravity wakes) from forming, an approximation that allows us to study long radial scales and to compare directly the hydrodynamic model and the N-body simulations. Our isothermal and non-isothermal hydrodynamic model results with vanishing self-gravity compare very well with results of Latter & Ogilvie and Rein & Latter, respectively. In contrast, for rings with radial self-gravity we find that the wavelengths of saturated overstable waves settle close to the frequency minimum of the nonlinear dispersion relation, i.e. close to a state of vanishing group velocities of the waves. Good agreement is found between non-isothermal hydrodynamics and N-body simulations for moderate and strong radial self-gravity, while the largest deviations occur for weak self-gravity. The resulting saturation wavelengths of viscous overstability for moderate and strong self-gravity (100-300m) agree reasonably well with the length scales of axisymmetric periodic micro-structure in Saturn's inner A-ring and the B-ring, as found by Cassini.