Stability of Jovian Trojans and their collisional families

Holt, Timothy R.; Nesvorný, David; Horner, Jonathan; King, Rachel; Marschall, Raphael; Kamrowski, Melissa; Carter, Brad; Brookshaw, Leigh; Tylor, Christopher

doi:10.1093/mnras/staa1348

Cited by 28 publications

(64 citation statements)

References 104 publications

(225 reference statements)

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“…The fraction of survivors for each small body population and for different T ML is shown in Figure 2. Overall, while the MBAs and TNOs are mostly stable with no more than a few per cent lost, 40% of the JTAs are removed during the ML phase; and we confirm that JTAs in the leading L4 cloud are more resistant by a few per cent than the trailing L5 cloud, in agreement with Di Sisto et al (2014); Holt et al (2020) (this phenomenon is also observed during the WD phase). Also, in the three simulations with different T ML and most apparently for the JTAs, it seems that when time is measured against the respective T ML , the small objects tend to be lost at the same time, i.e., when the planet-star mass ratio attains some certain value.…”

Section: Mass Loss Phasesupporting

confidence: 81%

“…Those objects are slowly diffusing, transversing various resonances and increasing eccentricity and inclination, causing close encounters with Jupiter and escape from the Trojan region (Robutel & Gabern 2006;Di Sisto et al 2019). The escape fraction from the L5 swarm is somewhat higher than that from L4 (Di Sisto et al 2014;Holt et al 2020). Lying in the immediate vicinity of Jupiter, the chance of collisions between the escaped JTAs with that planet becomes non-negligible, almost as frequent as that of reaching the WD Roche radius (Di Sisto et al 2019).…”

Section: White Dwarf Phasementioning

confidence: 99%

“…They have been captured by Jupiter during its early orbital migration (Nesvorný et al 2013;Pirani et al 2019). Those objects are slowly diffusing and leaking from the trojan region and perhaps ∼ 20% have been lost over the age of the solar system (e.g., Tsiganis et al 2005;Di Sisto et al 2014;Holt et al 2020). The escapees wander around in the solar system typically for a few Myr and a few per cent collide with the Sun (Di Sisto et al 2019).…”

Section: Introductionmentioning

confidence: 99%

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Metal pollution of the solar white dwarf by solar system small bodies

Li,

Mustill,

Davies

2021

Preprint

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White dwarfs (WDs) often show metal lines in their spectra, indicating accretion of asteroidal material. Our Sun is to become a WD in several Gyr. Here, we examine how the solar WD accretes from the three major small body populations: the main belt asteroids (MBAs), Jovian trojan asteroids (JTAs), and trans-Neptunian objects (TNOs). Owing to the solar mass loss during the giant branch, 40% of the JTAs are lost but the vast majority of MBAs and TNOs survive. During the WD phase, objects from all three populations are sporadically scattered onto the WD, implying ongoing accretion. For young cooling ages 100 Myr, accretion of MBAs predominates; our predicted accretion rate ∼ 10 6 g/s falls short of observations by two orders of magnitude. On Gyr timescales, thanks to the consumption of the TNOs that kicks in 100 Myr, the rate oscillates around 10 6 − 10 7 g/s until several Gyr and drops to ∼ 10 5 g/s at 10 Gyr. Our solar WD accretion rate from 1 Gyr and beyond agrees well with those of the extrasolar WDs. We show that for the solar WD, the accretion source region evolves in an inside-out pattern. Moreover, in a realistic small body population with individual sizes covering a wide range as WD pollutants, the accretion is dictated by the largest objects. As a consequence, the accretion rate is lower by an order of magnitude than that from a population of bodies of a uniform size and the same total mass and shows greater scatter.

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Section: Mass Loss Phasesupporting

confidence: 81%

Section: White Dwarf Phasementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Metal pollution of the solar white dwarf by solar system small bodies

Li,

Mustill,

Davies

2021

Preprint

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“…This is not unexpected since the dynamics around the L5 point is a mirror image of the L4 point in the restricted three-body problem. Furthermore, as noted in Section 1 and some other previous works (Nesvorný & Dones 2002;Di Sisto et al 2014;Holt et al 2020), under the gravitational effects of the four outer planets, the L4 and L5 Trojan swarms show almost the identical dynamical structure and stability in the long-term evolution. We thereby will only consider the L4 Jupiter Trojans in the following sections.…”

Section: Theoretical Approachsupporting

confidence: 73%

“…In this section, we still adopt the present outer solar system model, consisting of the Sun and four giant planets (i.e., Jupiter, Saturn, Uranus and Neptune). As in recent dynamical explorations of the Jupiter Trojans (e.g., Hellmich et al (2019), Holt et al (2020)), to construct robust simulations, we follow the long-term evolution of 30,000 test Trojans around the L4 point. Initially, all particles have the same semimajor axis (a ≈ 5.2 AU) with Jupiter.…”

Section: Apsidal Clustering: Reproductionmentioning

confidence: 99%

Apsidal asymmetric-alignment of Jupiter Trojans

Li,

Lei,

Xia

2021

Preprint

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The most distant Kuiper belt objects exhibit the clustering in their orbits, and this anomalous architecture could be caused by Planet 9 with large eccentricity and high inclination. We then suppose that the orbital clustering of minor planets may be observed somewhere else in the solar system. In this paper, we consider the over 7000 Jupiter Trojans from the Minor Planet Center, and find that they are clustered in the longitude of perihelion , around the locations J + 60 • and J − 60 • ( J is the longitude of perihelion of Jupiter) for the L4 and L5 swarms, respectively. Then we build a Hamiltonian system to describe the associated dynamical aspects for the co-orbital motion. The phase space displays the existence of the apsidally aligned islands of libration centered on ∆ = − J ≈ ±60 • , for the Trojan-like orbits with eccentricities e < 0.1. Through a detailed analysis, we have shown that the observed Jupiter Trojans with proper eccentricities e p < 0.1 spend most of their time in the range of |∆ | = 0 − 120 • , while the more eccentric ones with e p > 0.1 are too few to affect the orbital clustering within this ∆ range for the entire Trojan population. Our numerical results further prove that, even starting from a uniform ∆ distribution, the apsidal alignment of simulated Trojans similar to the observation can appear on the order of the age of the solar system. We conclude that the apsidal asymmetricalignment of Jupiter Trojans is robust, and this new finding can be helpful to design the survey strategy in the future.

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Origin and Evolution of Jupiter’s Trojan Asteroids

Bottke,

Marschall,

Nesvorný

et al. 2023

Space Sci Rev

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The origin of the Jupiter Trojan asteroids has long been a mystery. Dynamically, the population, which is considerably smaller than the main asteroid belt, librates around Jupiter’s stable L4 and L5 Lagrange points, 60 deg ahead and behind Jupiter. It is thought that these bodies were captured into these orbits early in solar system history, but any capture mechanism must also explain why the Trojans have an excited inclination distribution, with some objects reaching inclinations of 35°. The Trojans themselves, individually and in aggregate, also have spectral and physical properties that appear consistent with many small bodies found in the outer solar system (e.g., irregular satellites, Kuiper belt objects). In this review, we assemble what is known about the Trojans and discuss various models for their origin and collisional evolution. It can be argued that the Trojans are unlikely to be captured planetesimals from the giant planet zone, but instead were once denizens of the primordial Kuiper belt, trapped by the events taking place during a giant planet instability. The Lucy mission to the Trojans is therefore well positioned to not only answer questions about these objects, but also about their place in planet formation and solar system evolution studies.

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Stability of Jovian Trojans and their collisional families

Cited by 28 publications

References 104 publications

Metal pollution of the solar white dwarf by solar system small bodies

Metal pollution of the solar white dwarf by solar system small bodies

Apsidal asymmetric-alignment of Jupiter Trojans

Origin and Evolution of Jupiter’s Trojan Asteroids

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