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Main Authors: Proudfoot, Benjamin C. N., Ragozzine, Darin A., Giforos, William, Grundy, Will M., MacDonald, Mariah, Oldroyd, William J.
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2403.12782
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author Proudfoot, Benjamin C. N.
Ragozzine, Darin A.
Giforos, William
Grundy, Will M.
MacDonald, Mariah
Oldroyd, William J.
author_facet Proudfoot, Benjamin C. N.
Ragozzine, Darin A.
Giforos, William
Grundy, Will M.
MacDonald, Mariah
Oldroyd, William J.
contents The dwarf planet Haumea is one of the most compelling transneptunian objects (TNOs) to study, hosting two small, dynamically interacting satellites, a family of nearby spectrally unique objects, and a ring system. Haumea itself is extremely oblate due to its 3.9 hour rotation period. Understanding the orbits of Haumea's satellites, named Hi'iaka and Namaka, requires detailed modeling of both satellite-satellite gravitational interactions and satellite interactions with Haumea's nonspherical gravitational field (parameterized here as $J_2$). Understanding both of these effects allows for a detailed probe of the satellites' masses and Haumea's $J_2$ and spin pole. Measuring Haumea's $J_2$ provides information about Haumea's interior, possibly determining the extent of past differentation. In an effort to understand the Haumea system, we have performed detailed non-Keplerian orbit fitting of Haumea's satellites using a decade of new ultra-precise observations. Our fits detect Haumea's $J_2$ and spin pole at $\gtrsim2.5σ$ confidence. Degeneracies present in the dynamics prevent us from precisely measuring Haumea's $J_2$ with the current data, but future observations should enable a precise measurement. Our dynamically determined spin pole shows excellent agreement with past results, illustrating the strength of non-Keplerian orbit fitting. We also explore the spin-orbit dynamics of Haumea and its satellites, showing that axial precession of Hi'iaka may be detectable over decadal timescales. Finally, we present an ephemeris of the Haumea system over the coming decade, enabling high-quality observations of Haumea and its satellites for years to come.
format Preprint
id arxiv_https___arxiv_org_abs_2403_12782
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Beyond Point Masses. III. Detecting Haumea's Nonspherical Gravitational Field
Proudfoot, Benjamin C. N.
Ragozzine, Darin A.
Giforos, William
Grundy, Will M.
MacDonald, Mariah
Oldroyd, William J.
Earth and Planetary Astrophysics
The dwarf planet Haumea is one of the most compelling transneptunian objects (TNOs) to study, hosting two small, dynamically interacting satellites, a family of nearby spectrally unique objects, and a ring system. Haumea itself is extremely oblate due to its 3.9 hour rotation period. Understanding the orbits of Haumea's satellites, named Hi'iaka and Namaka, requires detailed modeling of both satellite-satellite gravitational interactions and satellite interactions with Haumea's nonspherical gravitational field (parameterized here as $J_2$). Understanding both of these effects allows for a detailed probe of the satellites' masses and Haumea's $J_2$ and spin pole. Measuring Haumea's $J_2$ provides information about Haumea's interior, possibly determining the extent of past differentation. In an effort to understand the Haumea system, we have performed detailed non-Keplerian orbit fitting of Haumea's satellites using a decade of new ultra-precise observations. Our fits detect Haumea's $J_2$ and spin pole at $\gtrsim2.5σ$ confidence. Degeneracies present in the dynamics prevent us from precisely measuring Haumea's $J_2$ with the current data, but future observations should enable a precise measurement. Our dynamically determined spin pole shows excellent agreement with past results, illustrating the strength of non-Keplerian orbit fitting. We also explore the spin-orbit dynamics of Haumea and its satellites, showing that axial precession of Hi'iaka may be detectable over decadal timescales. Finally, we present an ephemeris of the Haumea system over the coming decade, enabling high-quality observations of Haumea and its satellites for years to come.
title Beyond Point Masses. III. Detecting Haumea's Nonspherical Gravitational Field
topic Earth and Planetary Astrophysics
url https://arxiv.org/abs/2403.12782