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Tidal Evolution of the Eccentric Moon around Dwarf Planet (225088) Gonggong

Recent astronomical observations revealed that (225088) Gonggong, a 1000 km sized trans-Neptunian dwarf planet, hosts an eccentric satellite, Xiangliu, with an eccentricity of approximately 0.3. As the majority of known satellite systems around trans-Neptunian dwarf planets have circular orbits, the...

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Bibliographic Details
Published in:The Astronomical journal 2021-12, Vol.162 (6), p.226
Main Authors: Arakawa, Sota, Hyodo, Ryuki, Shoji, Daigo, Genda, Hidenori
Format: Article
Language:English
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Summary:Recent astronomical observations revealed that (225088) Gonggong, a 1000 km sized trans-Neptunian dwarf planet, hosts an eccentric satellite, Xiangliu, with an eccentricity of approximately 0.3. As the majority of known satellite systems around trans-Neptunian dwarf planets have circular orbits, the observed eccentricity of the Gonggong–Xiangliu system may reflect the singular properties of the system. In this study, we assumed that the Gonggong–Xiangliu system formed via a giant impact and we investigated the subsequent secular tidal evolution of this system under the simplifying assumptions of homogeneous bodies and of zero orbital inclination. We conducted simulations of coupled thermal–orbital evolution using the Andrade viscoelastic model and included higher-order eccentricity functions. The distribution of the final eccentricity from a large number of simulations with different initial conditions revealed that the radius of Xiangliu is not larger than 100 km. We also derived the analytical solution of the semilatus rectum evolution, a function of the radius of Xiangliu. From the point of view of the final semilatus rectum, the radius of Xiangliu was estimated to be close to 100 km. Together with the results of the Hubble Space Telescope observations, our findings suggest Gonggong and Xiangliu have similar albedos.
ISSN:0004-6256
1538-3881
DOI:10.3847/1538-3881/ac1f91