The excitation of planetary orbits by stellar jet variability and polarity reversal

Namouni, Fathi

doi:10.1007/s10509-012-1209-0

Cited by 2 publications

(4 citation statements)

References 43 publications

(43 reference statements)

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“…The observed differences in velocities between both jet components vary but may be approximated by a factor of about two. This factor agrees with the estimate of Namouni (2013) and his references. The asymmetry in the mass-loss rate may similarly be approximated by a factor of a few.…”

Section: Specific Examplessupporting

confidence: 93%

“…The disc itself provides another perturbation on the planet (and vice versa). Namouni (2005) and Namouni (2013), who also consider the effect on planets of bipolar jets, neglect the disc mass. We similarly neglect the disc, but first provide some more detailed justification for doing so.…”

Section: Context and Assumptionsmentioning

confidence: 99%

“…These studies include those by Boué et al (2012) and Iorio (2012), both of whom consider anisotropic evaporation from planetary atmospheres as the driver for orbital evolution. Investigators who instead consider asymmetric mass loss from the central star include Parriott & Alcock (1998), who quantify the escape of comets in different directions during post-MS evolution, and Namouni (2005), Namouni & Zhou (2006), Namouni & Guzzo (2007), and Namouni (2013), who instead look at the effects of bipolar jets on planetary orbits during the early stages of the life of a planetary system.…”

Section: Introductionmentioning

confidence: 99%

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An exoplanet's response to anisotropic stellar mass loss during birth and death

Veras

Hadjidemetriou

Tout

2013

Monthly Notices of the Royal Astronomical Society

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The birth and death of planets may be affected by mass outflows from their parent stars during the T-Tauri or post-main-sequence phases of stellar evolution. These outflows are often modelled to be isotropic, but this assumption is not realistic for fast rotators, bipolar jets and supernovae. Here we derive the general equations of motion for the time evolution of a single planet, brown dwarf, comet or asteroid perturbed by anisotropic mass loss in terms of a complete set of planetary orbital elements, the ejecta velocity, and the parent star's co-latitude and longitude. We restrict our application of these equations to 1) rapidly rotating giant stars, and 2) arbitrarily-directed jet outflows. We conclude that the isotropic mass-loss assumption can safely be used to model planetary motion during giant branch phases of stellar evolution within distances of hundreds of au. In fact, latitudinal mass loss variations anisotropically affect planetary motion only if the mass loss is asymmetric about the stellar equator. Also, we demonstrate how constant-velocity, asymmetric bipolar outflows in young systems incite orbital inclination changes. Consequently, this phenomenon readily tilts exoplanetary orbits external to a nascent disc on the order of degrees.

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Section: Specific Examplessupporting

confidence: 93%

Section: Context and Assumptionsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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An exoplanet's response to anisotropic stellar mass loss during birth and death

Veras

Hadjidemetriou

Tout

2013

Monthly Notices of the Royal Astronomical Society

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“…In astrophysics and dynamical astronomy, the Stark problem is sometimes known as the accelerated Kepler problem, and it is studied in several contexts. Models based on the accelerated Kepler problem have been used to study the excitation of planetary orbits by stellar jets in protoplanetary disks and to explain the origin of the eccentricities of extrasolar planets (Namouni 2005;Namouni & Guzzo 2007;Namouni 2013). The Stark problem has also been used in the study of the dynamics of dust grains in the Solar System (Belyaev & Rafikov 2010;Pástor 2012).…”

Section: Introductionmentioning

confidence: 99%

The Stark problem in the Weierstrassian formalism

Biscani¹,

Izzo²

2014

Monthly Notices of the Royal Astronomical Society

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We present a new general, complete closed-form solution of the three-dimensional Stark problem in terms of Weierstrass elliptic and related functions. With respect to previous treatments of the problem, our analysis is exact and valid for all values of the external force field, and it is expressed via unique formulae valid for all initial conditions and parameters of the system. The simple form of the solution allows us to perform a thorough investigation of the properties of the dynamical system, including the identification of quasi-periodic and periodic orbits, the formulation of a simple analytical criterion to determine the boundness of the trajectory, and the characterisation of the equilibrium points.

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The excitation of planetary orbits by stellar jet variability and polarity reversal

Cited by 2 publications

References 43 publications

An exoplanet's response to anisotropic stellar mass loss during birth and death

An exoplanet's response to anisotropic stellar mass loss during birth and death

The Stark problem in the Weierstrassian formalism

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