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Main Authors: Hahn, Joseph M., Hamilton, Douglas P., Rimlinger, Thomas, Luu, Lucy
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2505.06639
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author Hahn, Joseph M.
Hamilton, Douglas P.
Rimlinger, Thomas
Luu, Lucy
author_facet Hahn, Joseph M.
Hamilton, Douglas P.
Rimlinger, Thomas
Luu, Lucy
contents Narrow eccentric planetary ringlets have sharp edges, sizable eccentricity gradients, and a confinement mechanism that prevents radial spreading due to ring viscosity. Most proposed ringlet confinement mechanisms presume that there are one or more shepherd satellites whose gravitational perturbations keeps the ringlet confined radially, but the absence of such shepherds in Cassini observations of Saturn's rings casts doubt upon those ringlet confinement mechanisms. The following uses a suite of N-body simulations to explore an alternate scenario, whereby ringlet self-gravity drives a narrow eccentric ringlet into a self-confining state. These simulations show that, under a wide variety of initial conditions, an eccentric ringlet's secular perturbations of itself causes the eccentricity of its outer edge to grow at the expense of its inner edge. This causes the ringlet's nonlinearity parameter $q$ to grow over time until it exceeds the $q\simeq\sqrt{3}/2$ threshold where the ringlet's orbit-averaged angular momentum flux due to viscosity + self-gravity is zero. The absence of any net radial angular momentum transfer through the ringlet means that the ringlet has settled into a self-confining state, i.e. it does not spread radially due to its viscosity, and simulations also show that such ringlets have sharp edges. Nonetheless, viscosity still circularizes the ringlet in time $τ_e\sim10^6$ orbits $\sim1000$ years, which will cause the ringlet's nonlinearity parameter to shrink below the $q\simeq\sqrt{3}/2$ threshold and allows radial spreading to resume. Either sharp-edged narrow eccentric ringlets are transient phenomena, or exterior perturbations are also sustaining the ringlet's eccentricity. We then speculate about how such ringlets might come to be.
format Preprint
id arxiv_https___arxiv_org_abs_2505_06639
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle N-body simulations of the Self-Confinement of Viscous Self-Gravitating Narrow Eccentric Planetary Ringlets
Hahn, Joseph M.
Hamilton, Douglas P.
Rimlinger, Thomas
Luu, Lucy
Earth and Planetary Astrophysics
Narrow eccentric planetary ringlets have sharp edges, sizable eccentricity gradients, and a confinement mechanism that prevents radial spreading due to ring viscosity. Most proposed ringlet confinement mechanisms presume that there are one or more shepherd satellites whose gravitational perturbations keeps the ringlet confined radially, but the absence of such shepherds in Cassini observations of Saturn's rings casts doubt upon those ringlet confinement mechanisms. The following uses a suite of N-body simulations to explore an alternate scenario, whereby ringlet self-gravity drives a narrow eccentric ringlet into a self-confining state. These simulations show that, under a wide variety of initial conditions, an eccentric ringlet's secular perturbations of itself causes the eccentricity of its outer edge to grow at the expense of its inner edge. This causes the ringlet's nonlinearity parameter $q$ to grow over time until it exceeds the $q\simeq\sqrt{3}/2$ threshold where the ringlet's orbit-averaged angular momentum flux due to viscosity + self-gravity is zero. The absence of any net radial angular momentum transfer through the ringlet means that the ringlet has settled into a self-confining state, i.e. it does not spread radially due to its viscosity, and simulations also show that such ringlets have sharp edges. Nonetheless, viscosity still circularizes the ringlet in time $τ_e\sim10^6$ orbits $\sim1000$ years, which will cause the ringlet's nonlinearity parameter to shrink below the $q\simeq\sqrt{3}/2$ threshold and allows radial spreading to resume. Either sharp-edged narrow eccentric ringlets are transient phenomena, or exterior perturbations are also sustaining the ringlet's eccentricity. We then speculate about how such ringlets might come to be.
title N-body simulations of the Self-Confinement of Viscous Self-Gravitating Narrow Eccentric Planetary Ringlets
topic Earth and Planetary Astrophysics
url https://arxiv.org/abs/2505.06639