Dynamical essence of the eccentric von Zeipel-Lidov-Kozai effect in restricted hierarchical planetary systems

Lei, Hanlun; Gong, Yan-Xiang

doi:10.1051/0004-6361/202243746

Cited by 4 publications

(2 citation statements)

References 29 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In addition, there exists a third type, in which orbit flips happen with initial intermediate eccentricities. Sidorenko (2018) and Lei & Gong (2022b) demonstrated that the ELK effect is essentially a secular resonance and the flipping orbits are resonant trajectories with the resonant center located at i = 90°.…”

Section: = -mentioning

confidence: 99%

“…The related mechanism is referred as the ELK effect Naoz 2016). Recent research has demonstrated that the ELK effect is essentially a secular resonance with the critical argument j sign z v w = W + ( ) , i.e., the longitude of pericenter for prograde or retrograde orbits, which librates around 0 or π on a very long timescale (Sidorenko 2018; Lei 2022a; Lei & Gong 2022b). In this section, we are going to reveal a new orbit-flip mechanism by the combined ELK and stellar oblateness (J 2 ) effects.…”

Section: A New Type Of Orbit Flip With the Elk-j 2 Effectmentioning

confidence: 99%

See 1 more Smart Citation

An Orbit-flip Mechanism by Eccentric Lidov–Kozai Effect with Stellar Oblateness

2023

View full text Add to dashboard Cite

Orbit flips have been previously found under the eccentric Lidov–Kozai effect (ELK) in hierarchical three-body systems. Recently, we have found that, in certain conditions, the orbit can flip its orientation in a much different manner, where the stellar oblateness plays an important role. In this paper, orbit-flip behaviors with the ELK effect are investigated as the stellar oblateness varies within a wide range. This is of significance because recent works have shown that the oblateness of young stars has a widespread distribution and may have critical effects on sculpting the final orbital states of close-in planets. Our dynamical model includes the secular potential of the perturber to octupole order and the secular effects of the stellar oblateness. An alignment between the orbit plane of the outer perturber and the stellar bulge is assumed. Our findings mainly consist of two aspects. (i) A new type of orbit-flipping mechanism induced by a combination of the ELK and stellar oblateness effects, referred to as the ELK–J 2 effect, is discovered and confirmed. (ii) We demonstrate that, in the considered aligned configuration, the stellar oblateness suppresses orbit flips due to the ELK effect and produces new flips through the ELK–J 2 effect. Moreover, if the stellar oblateness perturbations are of the same order as the octupole perturbations of the outer perturber, the ELK-induced orbit flips are almost entirely suppressed, while the ELK–J 2 effect reaches its peak for the considered strength of the octupole perturbations. However, from a global view, stellar oblateness always reduces flipping orbits.

show abstract

Section: = -mentioning

confidence: 99%

Section: A New Type Of Orbit Flip With the Elk-j 2 Effectmentioning

confidence: 99%

An Orbit-flip Mechanism by Eccentric Lidov–Kozai Effect with Stellar Oblateness

2023

View full text Add to dashboard Cite

show abstract

Secular dynamics of stellar spin driven by planets inside Kozai–Lidov resonance

Lei

Gong

2023

Monthly Notices of the Royal Astronomical Society

View full text Add to dashboard Cite

In many exoplanetary systems with ‘hot Jupiters’, it is observed that the spin axes of host stars are highly misaligned to planetary orbital axes. In this study, a possible channel is investigated for producing such a misalignment under a hierarchical three-body system where the evolution of stellar spin is subjected to the gravitational torque induced from the planet inside Kozai–Lidov (KL) resonance. In particular, two special configurations are explored in detail. The first one corresponds to the configuration with planets at KL fixed points, and the second one corresponds to the configurations with planets moving on KL librating cycles. When the planet is located at the KL fixed point, the corresponding Hamiltonian model is of one degree of freedom and there are three branches of libration centres for stellar spin. When the planet is moving on KL cycles, the technique of Poincaré section is taken to reveal global structures of stellar spin in phase space. To understand the complex structures, perturbative treatments are adopted to study rotational dynamics. It shows that analytical structures in phase portraits under the resonant model can agree well with numerical structures arising in Poincaré sections, showing that the complicated dynamics of stellar spin are governed by the primary resonance under the unperturbed Hamiltonian model in combination with the 2:1 (high-order and/or secondary) spin-orbit resonances.

show abstract

Hierarchical three-body problem at high eccentricities = simple pendulum I: octupole

Klein,

Katz

2024

Monthly Notices of the Royal Astronomical Society: Letters

View full text Add to dashboard Cite

The gradual evolution of the restricted hierarchical three body problem is analyzed analytically, focusing on conditions of Kozai-Lidov Cycles that may lead to orbital flips from prograde to retrograde motion due to the octupole (third order) term which are associated with extremely high eccentricities. We revisit the approach described by Katz, Dong and Malhotra (2011) and show that for most initial conditions, to an excellent approximation, the analytic derivation can be greatly simplified and reduces to a simple pendulum model allowing an explicit flip criterion. The resulting flip criterion is much simpler than the previous one but the latter is still needed in a small fraction of phase space. We identify a logical error in the earlier derivation but clarify why it does not affect the final results.

show abstract

Dynamical essence of the eccentric von Zeipel-Lidov-Kozai effect in restricted hierarchical planetary systems

Cited by 4 publications

References 29 publications

An Orbit-flip Mechanism by Eccentric Lidov–Kozai Effect with Stellar Oblateness

An Orbit-flip Mechanism by Eccentric Lidov–Kozai Effect with Stellar Oblateness

Secular dynamics of stellar spin driven by planets inside Kozai–Lidov resonance

Hierarchical three-body problem at high eccentricities = simple pendulum I: octupole

Contact Info

Product

Resources

About