2019
DOI: 10.1093/mnras/stz2561
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Non–adiabatic tidal oscillations induced by a planetary companion

Abstract: We calculate the dynamical tides raised by a close planetary companion on nonrotating stars of 1 M and 1.4 M . Using the Henyey method, we solve the fully nonadiabatic equations throughout the star. The horizontal Lagrangian displacement is found to be 10 to 100 times larger than the equilibrium tide value in a thin region near the surface of the star. This is because non-adiabatic effects dominate in a region that extends from below the outer edge of the convection zone up to the stellar surface, and the equi… Show more

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Cited by 11 publications
(19 citation statements)
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“…The component of the Reynolds stress which couples to this shear is u r u ϕ . This is zero when there is no dissipation, as u r and u ϕ are π/2 out of phase in that case, but this could become significant in regions where dissipation is large, as this introduces an additional phase shift (e.g., Bunting, Papaloizou, & Terquem 2019). Dissipation of inertial waves in the convective envelope has also been considered as a possible explanation for the observed circularization periods.…”
Section: Discussionmentioning
confidence: 99%
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“…The component of the Reynolds stress which couples to this shear is u r u ϕ . This is zero when there is no dissipation, as u r and u ϕ are π/2 out of phase in that case, but this could become significant in regions where dissipation is large, as this introduces an additional phase shift (e.g., Bunting, Papaloizou, & Terquem 2019). Dissipation of inertial waves in the convective envelope has also been considered as a possible explanation for the observed circularization periods.…”
Section: Discussionmentioning
confidence: 99%
“…The equilibrium tide approximation is actually rather poor in convective regions where the Brunt-Väisälä frequency is not very large compared to the tidal frequency, and this yields to an over-estimate of tidal dissipation by a factor of a few for close binaries (Terquem et al 1998;Barker 2020). It also does not apply in a thin region near the surface of the convective envelope (Bunting, Papaloizou, & Terquem 2019). However, given all the uncertainties in estimating tidal dissipation here, the equilibrium tide approximation is sufficient.…”
Section: Transfer Of Energy Between the Tides And The Large Convectivmentioning
confidence: 99%
“…We follow Bunting et al (2019) and assume a non-rotating star with polar coordinates (r, θ * , φ * ) centred on the star, with the planetary companion existing in a circular orbit with θ * = π/2. In this frame, the observer is taken to be in the direction given by (θ 0 , φ 0 ).…”
Section: Set-upmentioning
confidence: 99%
“…The equilibrium tide approximation, whilst found to be reasonable throughout the bulk of the star (Pfahl et al 2008), breaks down at the stellar surface, where nonadiabatic effects become prominent (Henyey et al (1965); Savonije & Papaloizou (1983); Arras et al (2012); Houdek et al (2017); Fuller (2017)). The fully non-adiabatic stellar oscillation equations are solved here for the case of a periodic, tidal perturbation, as set out in Bunting et al (2019), with particular focus given to modelling the response at the surface.…”
Section: Introductionmentioning
confidence: 99%
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