TRACKING NEPTUNE'S MIGRATION HISTORY THROUGH HIGH-PERIHELION RESONANT TRANS-NEPTUNIAN OBJECTS

ABSTRACT Recently, Sheppard et al. presented the discovery of seven new trans-Neptunian objects with moderate eccentricities, perihelia beyond 40 au, and semimajor axes beyond 50 au. Like the few previously known objects on similar orbits, these objects' semimajor axes are just beyond the Kuipe...

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Bibliographic Details
Published in:The Astronomical journal 2016-11, Vol.152 (5), p.133-133
Main Authors: Kaib, Nathan A., Sheppard, Scott S.
Format: Article
Language:English
Subjects:
Fossils
Kuiper belt objects: individual (2015 KH162)
Kuiper belt: general
Mathematical models
Migration
Neptune
Orbital resonances (celestial mechanics)
Orbits
planet-disk interactions
planets and satellites: dynamical evolution and stability
planets and satellites: formation
planets and satellites: gaseous planets
Time
Trans-Neptunian objects
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Summary:ABSTRACT Recently, Sheppard et al. presented the discovery of seven new trans-Neptunian objects with moderate eccentricities, perihelia beyond 40 au, and semimajor axes beyond 50 au. Like the few previously known objects on similar orbits, these objects' semimajor axes are just beyond the Kuiper Belt edge and clustered around Neptunian mean motion resonances (MMRs). These objects likely obtained their observed orbits while trapped within MMRs, when the Kozai-Lidov mechanism raised their perihelia and weakened Neptune's dynamical influence. Using numerical simulations that model the production of this population, we find that high-perihelion objects near Neptunian MMRs can constrain the nature and timescale of Neptune's past orbital migration. In particular, the population near the 3:1 MMR (near 62 au) is especially useful due to its large population and short dynamical evolution timescale. If Neptune finishes migrating within ∼100 Myr or less, we predict that over 90% of high-perihelion objects near the 3:1 MMR will have semimajor axes within 1 au of each other, very near the modern resonance's center. On the other hand, if Neptune's migration takes ∼300 Myr, we expect ∼50% of this population to reside in dynamically fossilized orbits over ∼1 au closer to the Sun than the modern resonance. We highlight 2015 KH162 as a likely member of this fossilized 3:1 population. Under any plausible migration scenario, nearly all high-perihelion objects in resonances beyond the 4:1 MMR (near 76 au) reach their orbits well after Neptune stops migrating and compose a recently generated, dynamically active population.
ISSN:0004-6256
1538-3881
DOI:10.3847/0004-6256/152/5/133