Methods for computing giant planet formation and evolution

The discovery of gas giant planets around nearby stars has launched a new era in our understanding of the formation and evolution of planetary systems. However, none of the over four dozen companions detected to date strongly resembles Jupiter or Saturn: their inferred masses range from sub-Saturn-mass to 10 Jupiter-masses or more, while their orbits extend from periods of a few days to a few years. Given this situation, it seems prudent to re-examine mechanisms for gas giant planet formation. The two extreme cases are top-down or bottom-up. The latter is the core accretion mechanism, long favored for our Solar System, where a roughly 10 Earth-mass solid core forms by collisional accumulation of planetesimals, followed by hydrodynamic accretion of a gaseous envelope. The former is the long-discarded disk instability mechanism, where the protoplanetary disk forms self-gravitating, gaseous protoplanets through a gravitational instability of the gas, accompanied by settling and coagulation of dust grains to form solid cores. Both of these mechanisms have a number of advantages and disadvantages, making a purely theoretical choice between them difficult at present. Observations should be able to decide the dominant mechanism by dating the epoch of gas giant planet formation: core accretion requires more than a million years to form a Jupiter-mass planet, whereas disk instability is much more rapid.

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The Obliquity of HIP 67522 b: A 17 Myr Old Transiting Hot, Jupiter-sized Planet

The Astrophysical Journal ◽

10.3847/2041-8213/ac3485 ◽

2021 ◽

Vol 922 (1) ◽

pp. L1

Author(s):

Alexis Heitzmann ◽

George Zhou ◽

Samuel N. Quinn ◽

Stephen C. Marsden ◽

Duncan Wright ◽

...

Keyword(s):

Surface Brightness ◽

Planet Formation ◽

Giant Planet ◽

Young Stars ◽

Global Model ◽

High Eccentricity ◽

A Value ◽

Special Place ◽

Migration History ◽

Formation And Evolution

Abstract HIP 67522 b is a 17 Myr old, close-in (P orb = 6.96 days), Jupiter-sized (R = 10 R ⊕) transiting planet orbiting a Sun-like star in the Sco–Cen OB association. We present our measurement of the system’s projected orbital obliquity via two spectroscopic transit observations using the CHIRON spectroscopic facility. We present a global model that accounts for large surface brightness features typical of such young stars during spectroscopic transit observations. With a value of ∣ λ ∣ = 5.8 − 5.7 + 2.8 ° it is unlikely that this well-aligned system is the result of a high-eccentricity-driven migration history. By being the youngest planet with a known obliquity, HIP 67522 b holds a special place in contributing to our understanding of giant planet formation and evolution. Our analysis shows the feasibility of such measurements for young and very active stars.

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Giant planet formation with pebble accretion

Icarus ◽

10.1016/j.icarus.2014.01.036 ◽

2014 ◽

Vol 233 ◽

pp. 83-100 ◽

Cited By ~ 40

Author(s):

J.E. Chambers

Keyword(s):

Planet Formation ◽

Giant Planet

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Giant planet formation

Astrophysics of Planet Formation ◽

10.1017/cbo9780511802225.007 ◽

2012 ◽

pp. 185-217

Author(s):

Philip J. Armitage

Keyword(s):

Planet Formation ◽

Giant Planet

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Forming terrestrial planets and delivering water

Proceedings of the International Astronomical Union ◽

10.1017/s174392131600572x ◽

2015 ◽

Vol 11 (A29B) ◽

pp. 427-430

Author(s):

Kevin J. Walsh

Keyword(s):

Planet Formation ◽

Semimajor Axis ◽

Giant Planet ◽

Terrestrial Planet ◽

Giant Planets ◽

Asteroid Belt ◽

Terrestrial Planets ◽

The Earth ◽

Building Models ◽

Rich Material

AbstractBuilding models capable of successfully matching the Terrestrial Planet's basic orbital and physical properties has proven difficult. Meanwhile, improved estimates of the nature of water-rich material accreted by the Earth, along with the timing of its delivery, have added even more constraints for models to match. While the outer Asteroid Belt seemingly provides a source for water-rich planetesimals, models that delivered enough of them to the still-forming Terrestrial Planets typically failed on other basic constraints - such as the mass of Mars.Recent models of Terrestrial Planet Formation have explored how the gas-driven migration of the Giant Planets can solve long-standing issues with the Earth/Mars size ratio. This model is forced to reproduce the orbital and taxonomic distribution of bodies in the Asteroid Belt from a much wider range of semimajor axis than previously considered. In doing so, it also provides a mechanism to feed planetesimals from between and beyond the Giant Planet formation region to the still-forming Terrestrial Planets.

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Possible Rapid Gas Giant Planet Formation in the Solar Nebula and Other Protoplanetary Disks

The Astrophysical Journal ◽

10.1086/312737 ◽

2000 ◽

Vol 536 (2) ◽

pp. L101-L104 ◽

Cited By ~ 224

Author(s):

Alan P. Boss

Keyword(s):

Planet Formation ◽

Solar Nebula ◽

Giant Planet ◽

Protoplanetary Disks ◽

Gas Giant

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Gas giants in hot water: inhibiting giant planet formation and planet habitability in dense star clusters through cosmic time

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/stt102 ◽

2013 ◽

Vol 431 (1) ◽

pp. 63-79 ◽

Cited By ~ 31

Author(s):

Todd A. Thompson

Keyword(s):

Planet Formation ◽

Giant Planet ◽

Star Clusters ◽

Cosmic Time ◽

Hot Water

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Self-gravitating disks with Radiative Transfer: Their role in Giant Planet Formation

10.1063/1.3215821 ◽

2009 ◽

Author(s):

Farzana Meru ◽

Matthew R. Bate ◽

Tomonori Usuda ◽

Motohide Tamura ◽

Miki Ishii

Keyword(s):

Radiative Transfer ◽

Planet Formation ◽

Giant Planet

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Full exploration of the giant planet population around β Pictoris

Astronomy and Astrophysics ◽

10.1051/0004-6361/201730436 ◽

2018 ◽

Vol 612 ◽

pp. A108 ◽

Cited By ~ 11

Author(s):

A.-M. Lagrange ◽

M. Keppler ◽

N. Meunier ◽

J. Lannier ◽

H. Beust ◽

...

Keyword(s):

Extrasolar Planets ◽

Giant Planet ◽

Young Stars ◽

Giant Planets ◽

Close Orbit ◽

Wide Range ◽

Detection Probabilities ◽

Solar Type ◽

Formation And Evolution ◽

The One

Context. The search for extrasolar planets has been limited so far to close orbit (typ. ≤5 au) planets around mature solar-type stars on the one hand, and to planets on wide orbits (≥10 au) around young stars on the other hand. To get a better view of the full giant planet population, we have started a survey to search for giant planets around a sample of carefully selected young stars. Aims. This paper aims at exploring the giant planet population around one of our targets, β Pictoris, over a wide range of separations. With a disk and a planet already known, the β Pictoris system is indeed a very precious system for studies of planetary formation and evolution, as well as of planet–disk interactions. Methods. We analyse more than 2000 HARPS high-resolution spectra taken over 13 years as well as NaCo images recorded between 2003 and 2016. We combine these data to compute the detection probabilities of planets throughout the disk, from a fraction of au to a few dozen au. Results. We exclude the presence of planets more massive than 3 MJup closer than 1 au and further than 10 au, with a 90% probability. 15+ MJup companions are excluded throughout the disk except between 3 and 5 au with a 90% probability. In this region, we exclude companions with masses larger than 18 (resp. 30) MJup with probabilities of 60 (resp. 90) %.

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Magnetically induced termination of giant planet formation

Astronomy and Astrophysics ◽

10.1051/0004-6361/201833611 ◽

2018 ◽

Vol 619 ◽

pp. A165 ◽

Cited By ~ 7

Author(s):

A. J. Cridland

Keyword(s):

Magnetic Field ◽

Cross Section ◽

Planet Formation ◽

Giant Planet ◽

Effective Cross Section ◽

Cold Start ◽

Population Synthesis ◽

Hot Start ◽

Gas Accretion ◽

Planetary Magnetic Field

Here a physical model for terminating giant planet formation is outlined and compared to other methods of late-stage giant planet formation. As has been pointed out before, gas accreting into a gap and onto the planet will encounter the planetary dynamo-generated magnetic field. The planetary magnetic field produces an effective cross section through which gas is accreted. Gas outside this cross section is recycled into the protoplanetary disk, hence only a fraction of mass that is accreted into the gap remains bound to the planet. This cross section inversely scales with the planetary mass, which naturally leads to stalled planetary growth late in the formation process. We show that this method naturally leads to Jupiter-mass planets and does not invoke any artificial truncation of gas accretion, as has been done in some previous population synthesis models. The mass accretion rate depends on the radius of the growing planet after the gap has opened, and we show that so-called hot-start planets tend to become more massive than cold-start planets. When this result is combined with population synthesis models, it might show observable signatures of cold-start versus hot-start planets in the exoplanet population.

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