Saved in:
Bibliographic Details
Main Authors: Proudfoot, Benjamin, Grundy, Will, Ragozzine, Darin, Fernández-Valenzuela, Estela
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2511.07351
Tags: Add Tag
No Tags, Be the first to tag this record!
_version_ 1866912699028340736
author Proudfoot, Benjamin
Grundy, Will
Ragozzine, Darin
Fernández-Valenzuela, Estela
author_facet Proudfoot, Benjamin
Grundy, Will
Ragozzine, Darin
Fernández-Valenzuela, Estela
contents We present a detailed dynamical analysis of the Quaoar-Weywot system based on nearly 20 years of high-precision astrometric data, including new HST observations and stellar occultations. Our study reveals that Weywot's orbit deviates significantly from a purely Keplerian model, requiring the inclusion of Quaoar's non-spherical gravitational field and center-of-body-center-of-light (COB-COL) offsets in our orbit models. We place a robust upper limit on Weywot's orbital eccentricity ($e<0.02$), substantially lower than previous estimates, which has important implications for the strength of mean motion resonances (MMRs) acting on Quaoar's ring system. Under the assumption that Quaoar's rings lie in its equatorial plane, we detect Quaoar's dynamical oblateness, $J_2$, at $\sim$2$σ$ confidence. The low $J_2$ value found under that assumption implies Quaoar is differentiated, with a total bulk density of $1751\pm13$ (stat.) kg m$^{-3}$. Additionally, we detect significant COB-COL offsets likely arising from latitudinal albedo variations across Quaoar's surface. These offsets are necessary to achieve a statistically robust orbit fit and highlight the importance of accounting for surface heterogeneity when modeling the orbits of dwarf planet moons. These findings improve our understanding of Quaoar's interior and surface while providing key insights into the stability and confinement mechanisms of its rings.
format Preprint
id arxiv_https___arxiv_org_abs_2511_07351
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Beyond Point Masses. V. Weywot's Non-Keplerian Orbit
Proudfoot, Benjamin
Grundy, Will
Ragozzine, Darin
Fernández-Valenzuela, Estela
Earth and Planetary Astrophysics
We present a detailed dynamical analysis of the Quaoar-Weywot system based on nearly 20 years of high-precision astrometric data, including new HST observations and stellar occultations. Our study reveals that Weywot's orbit deviates significantly from a purely Keplerian model, requiring the inclusion of Quaoar's non-spherical gravitational field and center-of-body-center-of-light (COB-COL) offsets in our orbit models. We place a robust upper limit on Weywot's orbital eccentricity ($e<0.02$), substantially lower than previous estimates, which has important implications for the strength of mean motion resonances (MMRs) acting on Quaoar's ring system. Under the assumption that Quaoar's rings lie in its equatorial plane, we detect Quaoar's dynamical oblateness, $J_2$, at $\sim$2$σ$ confidence. The low $J_2$ value found under that assumption implies Quaoar is differentiated, with a total bulk density of $1751\pm13$ (stat.) kg m$^{-3}$. Additionally, we detect significant COB-COL offsets likely arising from latitudinal albedo variations across Quaoar's surface. These offsets are necessary to achieve a statistically robust orbit fit and highlight the importance of accounting for surface heterogeneity when modeling the orbits of dwarf planet moons. These findings improve our understanding of Quaoar's interior and surface while providing key insights into the stability and confinement mechanisms of its rings.
title Beyond Point Masses. V. Weywot's Non-Keplerian Orbit
topic Earth and Planetary Astrophysics
url https://arxiv.org/abs/2511.07351