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Main Authors: Chen, Yue, Li, Jian
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2411.00829
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author Chen, Yue
Li, Jian
author_facet Chen, Yue
Li, Jian
contents To incorporate the gravitational influence of Kuiper belt objects (KBOs) in planetary ephemerides, uniform-ring models are commonly employed. In this paper, for representing the KBO population residing in Neptune's 2:3 mean motion resonance (MMR), known as the Plutinos, we introduce a three-arc model by considering their resonant characteristics. Each `arc' refers to a segment of the uniform ring and comprises an appropriate number of point masses. Then the total perturbation of Plutinos is numerically measured by the change in the Sun-Neptune distance ($Δd_{SN}$). We conduct a comprehensive investigation to take into account various azimuthal and radial distributions associated with the resonant amplitudes ($A$) and eccentricities ($e$) of Plutinos, respectively. The results show that over a 100-year period: (1) at the smallest $e=0.05$, the Sun-Neptune distance change $Δd_{SN}$ caused by Plutinos decreases significantly as $A$ reduces. It can deviate from the value of $Δd_{SN}$ obtained in the ring model by approximately 100 km; (2) as $e$ increases in the medium range of 0.1-0.2, the difference in $Δd_{SN}$ between the arc and ring models becomes increasingly significant; (3) at the largest $e\gtrsim0.25$, $Δd_{SN}$ can approach zero regardless of $A$, and the arc and ring models exhibit a substantial difference in $Δd_{SN}$, reaching up to 170 km. Then the applicability of our three-arc model is further verified by comparing it to the perturbations induced by observed Plutinos on the positions of both Neptune and Saturn. Moreover, the concept of the multiple-arc model, designed for Plutinos, can be easily extended to other MMRs densely populated by small bodies.
format Preprint
id arxiv_https___arxiv_org_abs_2411_00829
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle A new multiple-arc model of the resonant Kuiper belt objects -- Plutinos
Chen, Yue
Li, Jian
Earth and Planetary Astrophysics
To incorporate the gravitational influence of Kuiper belt objects (KBOs) in planetary ephemerides, uniform-ring models are commonly employed. In this paper, for representing the KBO population residing in Neptune's 2:3 mean motion resonance (MMR), known as the Plutinos, we introduce a three-arc model by considering their resonant characteristics. Each `arc' refers to a segment of the uniform ring and comprises an appropriate number of point masses. Then the total perturbation of Plutinos is numerically measured by the change in the Sun-Neptune distance ($Δd_{SN}$). We conduct a comprehensive investigation to take into account various azimuthal and radial distributions associated with the resonant amplitudes ($A$) and eccentricities ($e$) of Plutinos, respectively. The results show that over a 100-year period: (1) at the smallest $e=0.05$, the Sun-Neptune distance change $Δd_{SN}$ caused by Plutinos decreases significantly as $A$ reduces. It can deviate from the value of $Δd_{SN}$ obtained in the ring model by approximately 100 km; (2) as $e$ increases in the medium range of 0.1-0.2, the difference in $Δd_{SN}$ between the arc and ring models becomes increasingly significant; (3) at the largest $e\gtrsim0.25$, $Δd_{SN}$ can approach zero regardless of $A$, and the arc and ring models exhibit a substantial difference in $Δd_{SN}$, reaching up to 170 km. Then the applicability of our three-arc model is further verified by comparing it to the perturbations induced by observed Plutinos on the positions of both Neptune and Saturn. Moreover, the concept of the multiple-arc model, designed for Plutinos, can be easily extended to other MMRs densely populated by small bodies.
title A new multiple-arc model of the resonant Kuiper belt objects -- Plutinos
topic Earth and Planetary Astrophysics
url https://arxiv.org/abs/2411.00829