Abstract
Star-planet tidal interactions may result in the excitation of inertial waves in the convective region of stars. In low-mass stars, their dissipation plays a prominent role in the long-term orbital evolution of short-period planets. Turbulent convection can sustain differential rotation in their envelope, with an equatorial acceleration (as in the Sun) or deceleration, which can modify the waves' propagation properties. We explore in this first paper the general propagation properties of free linear inertial waves in a differentially rotating homogeneous fluid inside a spherical shell. We assume that the angular velocity background flow depends on the latitudinal coordinate only, close to what is expected in the external convective envelope of low-mass stars. We use i) an analytical approach in the inviscid case to get the dispersion relation, from which we compute the characteristic trajectories along which energy propagates. This allows us to study the existence of attractor cycles and infer the different families of inertial modes; ii) high-resolution numerical calculations based on a spectral method for the viscous problem. We find that modes that propagate in the whole shell (D modes) behave the same way as with solid-body rotation. However, another family of inertial modes exists (DT modes), which can propagate only in a restricted part of the convective zone. Our study shows that they are less common than D modes and that the characteristic rays and shear layers often focus towards a wedge - or point-like attractor. More importantly, we find that for non-axisymmetric oscillation modes, shear layers may cross a corotation resonance with a local accumulation of kinetic energy. Their damping rate scales very differently from what we obtain for standard D modes and we show an example where it is independent of viscosity (Ekman number) in the astrophysical regime in which it is small.
Highlights
The tidal interaction between a star and its orbiting companion results from the differential force exerted by each body on the other
We investigated the impact of conical differential rotation on the properties of free inertial waves in a homogeneous fluid inside a spherical shell container
We found that differential rotation implies different families of inertial waves and that the frequency range in which they exist can be broadened substantially compared to the solidbody rotation case, provided that a large enough latitudinal differential rotation exists in the convective envelopes of low-mass stars (Brun & Toomre 2002; Brown et al 2008; Matt et al 2011)
Summary
The tidal interaction between a star and its orbiting companion results from the differential force exerted by each body on the other. The dynamical tide consists of low-frequency oscillations primarily restored by the Coriolis acceleration, known as inertial waves, that propagate in a sphere (if the body is fully convective) or a spherical shell (for Sun-like stars with an outer convective envelope) These waves were studied long ago in a uniformly rotating, incompressible and inviscid fluid by Thomson (1880), Poincaré (1885), Bryan (1889), and Cartan (1922) (and Greenspan 1968), and they exhibit remarkable properties: their frequency ωin the fluid frame (rotating with angular velocity Ω) is restricted to [−2Ω, 2Ω], while their spatial structure is governed by a hyperbolic second-order partial differential equation named after Poincaré.
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