An internal heating mechanism operating in ultra-short-period planets orbiting magnetically active stars
Journal
Date Issued
2021
Author(s)
Abstract
A new mechanism for the internal heating of ultra-short-period planets is
proposed based on the gravitational perturbation by a non-axisymmetric
quadrupole moment of their host stars. Such a quadrupole is due to the magnetic
flux tubes in the stellar convection zone, unevenly distributed in longitude
and persisting for many stellar rotations as observed in young late-type stars.
The rotation period of the host star evolves from its shortest value on the
zero-age main sequence to longer periods due to the loss of angular momentum
through a magnetized wind. If the stellar rotation period comes close to twice
the orbital period of the planet, the quadrupole leads to a spin-orbit
resonance that excites oscillations of the star-planet separation. As a
consequence, a strong tidal dissipation is produced inside the planet. We
illustrate the operation of the mechanism by modeling the evolution of the
stellar rotation and of the innermost planetary orbit in the cases of CoRoT-7,
Kepler-78, and K2-141 whose present orbital periods range between 0.28 and 0.85
days. If the spin-orbit resonance occurs, the maximum power dissipated inside
the planets ranges between $10^{18}$ and $10^{19}$ W, while the total
dissipated energy is of the order of $10^{30}-10^{32}$ J over a time interval
as short as $(1-4.5) \times 10^{4}$ yr. Such a huge heating over a so short
time interval produces a complete melting of the planetary interiors and may
shut off their hydromagnetic dynamos. These may initiate a successive phase of
intense internal heating owing to unipolar magnetic star-planet interactions
and affect the composition and the escape of their atmospheres, producing
effects that could be observable during the entire lifetime of the planets
[abridged abstract].
Volume
653
Start page
A112
Issn Identifier
0004-6361
Rights
open.access
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