Formation and evolution of the two 4/3 resonant giants planets in HD 200964

Santos, M. Tadeu dos; Correa-Otto, J. A.; Michtchenko, T. A.; Ferraz-Mello, S.

doi:10.1051/0004-6361/201424820

Cited by 14 publications

(15 citation statements)

References 53 publications

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“…The resonant angle of the first planet circulates from 0 • to 360 • , while σ c is librating around 180 • . The confinement of σ c around 180 • shows that it is the truly resonant librating angle of the 7 CMa system, as shown previously for the HD 200964 system by Tadeu dos Santos et al (2015). Therefore, we can conclude that the two-planet system is effectively trapped in the narrow stable region of the 4:3 mean motion resonance and that the stability analysis reveals the true configuration of the system.…”

Section: Dynamical Propertiessupporting

confidence: 82%

“…Rein et al (2012) reached the same conclusions using hydrodynamical simulations of convergent migration and in-situ formation. On the other hand, Tadeu dos Santos et al (2015) were able to reproduce the formation process of HD 200964 using models that contained an interaction between the type I and type II of migration, planetary growth and stellar evolution from the main sequence to the sub-giant branch. However, the authors pointed out that the formation process is very sensitive to the planetary masses and protoplanetary disk parameters, where only a thin, vertically isothermal and laminar disk, with a nearly constant surface density profile allows the embryo-sized planets to reach the 4:3 resonant configuration.…”

Section: Discussionmentioning

confidence: 99%

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Precise radial velocities of giant stars XIII. A second Jupiter orbiting in 4:3 resonance in the 7 CMa system

Luque,

Trifonov,

Reffert

et al. 2019

Preprint

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We report the discovery of a second planet orbiting the K giant star 7 CMa based on 166 high-precision radial velocities obtained with Lick, HARPS, UCLES and SONG. The periodogram analysis reveals two periodic signals of approximately 745 and 980 d, associated to planetary companions. A double-Keplerian orbital fit of the data reveals two Jupiter-like planets with minimum masses m b sin i ∼ 1.9 M J and m c sin i ∼ 0.9 M J , orbiting at semi-major axes of a b ∼ 1.75 au and a c ∼ 2.15 au, respectively. Given the small orbital separation and the large minimum masses of the planets close encounters may occur within the time baseline of the observations, thus, a more accurate N-body dynamical modeling of the available data is performed. The dynamical best-fit solution leads to collision of the planets and we explore the long-term stable configuration of the system in a Bayesian framework, confirming that 13% of the posterior samples are stable for at least 10 Myr. The result from the stability analysis indicates that the two-planets are trapped in a low-eccentricity 4:3 mean-motion resonance. This is only the third discovered system to be inside a 4:3 resonance, making it very valuable for planet formation and orbital evolution models.

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Section: Dynamical Propertiessupporting

confidence: 82%

Section: Discussionmentioning

confidence: 99%

Precise radial velocities of giant stars XIII. A second Jupiter orbiting in 4:3 resonance in the 7 CMa system

Luque,

Trifonov,

Reffert

et al. 2019

Preprint

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show abstract

“…As the value of p increases, and the configuration approaches a co-orbital state, the probability of capture decreases. Nevertheless, Tadeu dos Santos et al (2015) illustrated how planets can bypass -or migrate throughthe 2:1 and 3:2 mean motion resonances to become trapped in the 4:3 mean motion resonance. Similarly, figures 9 and 7 of Papaloizou & Szuszkiewicz (2005) respectively illustrated how entrapment into the 6:5 and 9:8 mean motion resonances may be possible; Quillen, et al (2013)…”

Section: Types Of Resonancesmentioning

confidence: 99%

Speeding past planets? Asteroids radiatively propelled by giant branch Yarkovsky effects

Veras

Higuchi

Ida

2019

Monthly Notices of the Royal Astronomical Society

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Understanding the fate of planetary systems through white dwarfs which accrete debris crucially relies on tracing the orbital and physical properties of exo-asteroids during the giant branch phase of stellar evolution. Giant branch luminosities exceed the Sun's by over three orders of magnitude, leading to significantly enhanced Yarkovsky and YORP effects on minor planets. Here, we place bounds on Yarkovsky-induced differential migration between asteroids and planets during giant branch mass loss by modelling one exo-Neptune with inner and outer exo-Kuiper belts. In our bounding models, the asteroids move too quickly past the planet to be diverted from their eventual fate, which can range from: (i) populating the outer regions of systems out to 10 4 − 10 5 au, (ii) being engulfed within the host star, or (iii) experiencing Yarkovsky-induced orbital inclination flipping without any Yarkovsky-induced semimajor axis drift. In these violent limiting cases, temporary resonant trapping of asteroids with radii of under about 10 km by the planet is insignificant, and capture within the planet's Hill sphere requires fine-tuned dissipation. The wide variety of outcomes presented here demonstrates the need to employ sophisticated structure and radiative exo-asteroid models in future studies. Determining where metal-polluting asteroids reside around a white dwarf depends on understanding extreme Yarkovsky physics.

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“…The HD 200964 system is similar to 24 Sex in terms of stellar mass and minimum planetary masses, but it has a much more compact orbital configuration, with periods of P b ≈ 610 and P c ≈ 830 days. The HD 200964 system is only stable if the orbits are in a 4:3 MMR (Wittenmyer et al 2012;Tadeu dos Santos et al 2015).…”

Section: Tight Jovian Pairs Around Evolved Starsmentioning

confidence: 99%

Two Jovian Planets around the Giant Star HD 202696: A Growing Population of Packed Massive Planetary Pairs around Massive Stars?

Trifonov

Stock

Henning

et al. 2019

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We present evidence for a new two-planet system around the giant star HD 202696 (= HIP 105056, BD +26 4118). The discovery is based on public HIRES radial velocity (RV) measurements taken at Keck Observatory between 2007 July and 2014 September. We estimate a stellar mass of 1.91 +0.09 −0.14 M for HD 202696, which is located close to the base of the red giant branch. A two-planet self-consistent dynamical modeling MCMC scheme of the RV data followed by a long-term stability test suggests planetary orbital periods of P b = 517.8 +8.9 −3.9 and P c = 946.6 +20.7 −20.9 days, eccentricities of e b = 0.011 +0.078 −0.011 and e c = 0.028 +0.065 −0.012 , and minimum dynamical masses of m b = 2.00 +0.22 −0.10 M Jup and m c = 1.86 +0.18 −0.23M Jup , respectively. Our stable MCMC samples are consistent with orbital configurations predominantly in a mean period ratio of 11:6 and its close-by high-order mean-motion commensurabilities with low eccentricities. For the majority of the stable configurations, we find an aligned or anti-aligned apsidal libration (i.e. ∆ω librating around 0 • or 180 • ), suggesting that the HD 202696 system is likely dominated by secular perturbations near the high-order 11:6 mean-motion resonance. The HD 202696 system is yet another Jovian-mass pair around an intermediate-mass star with a period ratio below the 2:1 mean-motion resonance. Therefore, the HD 202696 system is an important discovery, that may shed light on the primordial disk-planet properties needed for giant planets to break the strong 2:1 mean motion resonance and settle in more compact orbits.

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Formation and evolution of the two 4/3 resonant giants planets in HD 200964

Cited by 14 publications

References 53 publications

Precise radial velocities of giant stars XIII. A second Jupiter orbiting in 4:3 resonance in the 7 CMa system

Precise radial velocities of giant stars XIII. A second Jupiter orbiting in 4:3 resonance in the 7 CMa system

Speeding past planets? Asteroids radiatively propelled by giant branch Yarkovsky effects

Two Jovian Planets around the Giant Star HD 202696: A Growing Population of Packed Massive Planetary Pairs around Massive Stars?

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