Fly-by encounters between two planetary systems I: Solar system analogues

Li, Daohai; Mustill, Alexander J.; Davies, Melvyn B.

doi:10.1093/mnras/stz1794

Cited by 39 publications

(29 citation statements)

References 63 publications

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“…For example, it becomes 42% for q enc = 0.012 au and 93% at 0.024 au. This agrees with the case of planet capture during stellar encounters, where during a distant flyby, all planets lost (if any) from one star are captured by the other (Li et al 2019). Because the number of moons captured during encounters with q enc = 0.024 au is limited, we do not analyse them in detail.…”

Section: Loss and Capture In Generalsupporting

confidence: 71%

Capture of satellites during planetary encounters

Johansen

Mustill

et al. 2020

A&A

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Context. Single-binary scattering may lead to an exchange where the single object captures a component of the binary, forming a new binary. This has been well studied in encounters between a star–planet pair and a single star. Aims. Here we explore the application of the exchange mechanism to a planet–satellite pair and another planet in the gravitational potential of a central star. As a case study, we focus on encounters between a satellite-bearing object and Neptune. We investigate whether Neptune can capture satellites from that object and if the captured satellites have orbits analogous to the Neptunian moons Triton and Nereid. Methods. Using N-body simulations, we study the capture probability at different encounter distances. Post-capture, we use a simple analytical argument to estimate how the captured orbits evolve under collisional and tidal effects. Results. We find that the average capture probability reaches ~10% if Neptune penetrates the donor planet’s satellite system. Most moons grabbed by Neptune acquire highly eccentric orbits. Post-capture, around half of those captured, especially those on tight orbits, can be circularised, either by tides only or by collisions+tides, turning into Triton-like objects. Captures further out, on the other hand, stay on wide and eccentric orbits like that of Nereid. Both moon types can be captured in the same encounter and they have wide distributions in orbital inclination. Therefore, Triton naturally has a ~50% chance of being retrograde. Conclusions. A similar process potentially applies to an exoplanetary system, and our model predicts that exomoons can jump from one planet to another during planetary scattering. Specifically, there should be two distinct populations of captured moons: one on close-in circular orbits and the other on far-out eccentric orbits. The two populations may have highly inclined prograde or retrograde orbits.

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Section: Loss and Capture In Generalsupporting

confidence: 71%

Capture of satellites during planetary encounters

Johansen

Mustill

et al. 2020

A&A

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“…At higher densities, they often eject the planet altogether 114 . However, for initial semi-major axes of a p 1 au, stellar encounters can significantly alter exoplanet architectures even in clusters of moderate densities (∼ 100 stars pc −3 ) 66,115 . Recent simulations have tried to address this problem by taking a population synthesis approach 116 .…”

Section: Bimodal Exoplanet Propertiesmentioning

confidence: 99%

Stellar clustering shapes the architecture of planetary systems

Winter

Kruijssen

Longmore

et al. 2020

Nature

109

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Planet formation is generally described in terms of a system containing the host star and a protoplanetary disk 1 – 3 , of which the internal properties (for example, mass and metallicity) determine the properties of the resulting planetary system 4 . However, (proto)planetary systems are predicted 5 , 6 and observed 7 , 8 to be affected by the spatially clustered stellar formation environment, through either dynamical star–star interactions or external photoevaporation by nearby massive stars 9 . It is challenging to quantify how the architecture of planetary sysems is affected by these environmental processes, because stellar groups spatially disperse within less than a billion years 10 , well below the ages of most known exoplanets. Here we identify old, co-moving stellar groups around exoplanet host stars in the astrometric data from the Gaia satellite 11 , 12 and demonstrate that the architecture of planetary systems exhibits a strong dependence on local stellar clustering in position-velocity phase space. After controlling for host stellar age, mass, metallicity and distance from the star, we obtain highly significant differences (with p values of 10 −5 to 10 −2 ) in planetary system properties between phase space overdensities (composed of a greater number of co-moving stars than unstructured space) and the field. The median semi-major axis and orbital period of planets in phase space overdensities are 0.087 astronomical units and 9.6 days, respectively, compared to 0.81 astronomical units and 154 days, respectively, for planets around field stars. ‘Hot Jupiters’ (massive, short-period exoplanets) predominantly exist in stellar phase space overdensities, strongly suggesting that their extreme orbits originate from environmental perturbations rather than internal migration 13 , 14 or planet–planet scattering 15 , 16 . Our findings reveal that stellar clustering is a key factor setting the architectures of planetary systems.

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“…The encounters between these planetary systems in a cluster can be studied either in a Monte Carlo approach in the sense that the encounters are directly generated according to the expected distribution (e.g., Laughlin & Adams 1998;Malmberg et al 2011;Hao et al 2013;Li et al 2019) or in a selfconsistent cluster simulation where thus the frequency and parameters of the flybys flybys are more accurately modelled (see Spurzem et al 2009;Cai et al 2017;van Elteren et al 2019;Fujii & Hori 2019, for instance). Here we follow Paper I and adopt the first method.…”

Section: Encounter Setupmentioning

confidence: 99%

“…This probably results from the combination of the effect of the more closely-packed and more massive inner planets themselves and the contribution from the outer gas giant Kepler-48 e. That planet itself is more susceptible due to its larger stellar-centric distance. Just like Jupiter in the solar system (Hao et al 2013;Li et al 2019), it is indestructible in the post-encounter phase owing to its dominance in the systems's mass budget. The top panel of Figure 5 shows the stability of the system.…”

Section: Kepler-48 System: Flyby By a Single Sunmentioning

confidence: 99%

Fly-by encounters between two planetary systems II: Exploring the interactions of diverse planetary system architectures

Li,

Mustill,

Davies

2020

Preprint

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Planetary systems formed in clusters may be subject to stellar encounter flybys. Here we create a diverse range of representative planetary systems with different orbital scales and planets' masses and examine encounters between them in a typical open cluster. We first explore the close-in multi-super earth systems 0.1 au. They are resistant to flybys in that only ones inside a few au can destabilise a planet or break the resonance between such planets. But these systems may capture giant planets onto wide orbits from the intruding star during distant flybys. If so, the original close-in small planets' orbits may be tilted together through Kozai-Lidov mechanism, forming a "cold" system that is significantly inclined against the equator of the central host. Moving to the intermediately-placed planets around solar-like stars, we find that the planets' mass gradient governs the systems' long-term evolution post-encounter: more massive planets have better chances to survive. Also, a system's angular momentum deficit, a quantity describing how eccentric/inclined the orbits are, measured immediately after the encounter, closely relates to the longevity of the systems -whether or not and when the systems turn unstable in the ensuing evolution millions of years post-encounter. We compare the orbits of the surviving planets in the unstable systems through (1) the immediate consequence of the stellar fly or (2) internal interplanetary scattering long post-encounter and find that those for the former are systematically colder. Finally, we show that massive wide-orbit multi-planet systems like that of HR 8799 can be easily disrupted and encounters at a few hundreds of au suffice.

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Fly-by encounters between two planetary systems I: Solar system analogues

Cited by 39 publications

References 63 publications

Capture of satellites during planetary encounters

Capture of satellites during planetary encounters

Stellar clustering shapes the architecture of planetary systems

Fly-by encounters between two planetary systems II: Exploring the interactions of diverse planetary system architectures

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