278 research outputs found
The determination of planetary structure in tidally relaxed inclined systems
[Abridged] The recent discovery of a transiting planet on a non-circular
orbit with a massive highly eccentric companion orbiting HAT-P-13 offers the
possibility of probing the structure of the short-period planet. The ability to
do this relies on the system being in a quasi-equilibrium state in the sense
that the eccentricities are constant on the usual secular timescale, and decay
on a timescale which is much longer than the age of the system. Since the
equilibrium eccentricity is effectively a function only of observable system
parameters and the unknown Love number of the short-period planet, the latter
can be determined with accurate measurements of the planet's eccentricity and
radius. However, this analysis relies on the unlikely assumption that the
system is coplanar. Here we generalize our recent analysis of this fixed-point
phenomenon to mutually inclined systems and show that the fixed point of
coplanar systems is replaced by a limit cycle, with the average value of the
eccentricity decreasing and its amplitude of variation increasing with
increasing mutual inclination. This behaviour significantly reduces the ability
to unambiguously determine the Love number of the short-period planet if the
mutual inclination is higher than around 10^o. We show that for Q-values less
than 10^6, the HAT-P-13 system cannot have a mutual inclination between 54 and
126^o because Kozai oscillations coupled with tidal dissipation would act to
quickly move the inclination outside this range, and that the behaviour of
retrograde systems is the mirror image of that for prograde systems. We derive
a relationship between the equilibrium radius of the short-period planet, its
Q-value and its core mass, and show that given current estimates of e_b and the
planet radius, the HAT-P-13 system is likely to be close to coplanar [...]Comment: 24 pages, 14 figures, Accepted for publication in MNRAS. **NOTE
REFINED PREDICTION FOR MUTUAL INCLINATIO
On the Survival of Short-Period Terrestrial Planets
The currently feasible method of detection of Earth-mass planets is transit
photometry, with detection probability decreasing with a planet's distance from
the star. The existence or otherwise of short-period terrestrial planets will
tell us much about the planet formation process, and such planets are likely to
be detected first if they exist. Tidal forces are intense for short-period
planets, and result in decay of the orbit on a timescale which depends on
properties of the star as long as the orbit is circular. However, if an
eccentric companion planet exists, orbital eccentricity () is induced and
the decay timescale depends on properties of the short-period planet, reducing
by a factor of order if it is terrestrial. Here we examine the
influence companion planets have on the tidal and dynamical evolution of
short-period planets with terrestrial structure, and show that the relativistic
potential of the star is fundamental to their survival.Comment: 13 pages, 2 figures, accepted for publication in Ap
Long-term tidal evolution of short-period planets with companions
Of the fourteen transiting extrasolar planetary systems for which radii have
been measured, at least three appear to be considerably larger than theoretical
estimates suggest. It has been proposed by Bodenheimer, Lin & Mardling that
undetected companions acting to excite the orbital eccentricity are responsible
for these oversized planets, as they find new equilibrium radii in response to
being tidally heated. In the case of HD 209458, this hypothesis has been
rejected by some authors because there is no sign of such a companion at the 5
m/s level, and because it is difficult to say conclusively that the
eccentricity is non-zero. Transit timing analysis [...]. Whether or not a
companion is responsible for the large radius of HD 209458b, almost certainly
some short-period systems have companions which force their eccentricities to
nonzero values. This paper is dedicated to quantifying this effect.
The eccentricity of a short-period planet will only be excited as long as its
(non-resonant) companion's eccentricity is non-zero. Here we show that the
latter decays on a timescale which depends on the structure of the interior
planet, a timescale which is often shorter than the lifetime of the system.
This includes Earth-mass planets in the habitable zones of some stars. We
determine which configurations are capable of sustaining significant
eccentricity for at least the age of the system, and show that these include
systems with companion masses as low as a fraction of an Earth mass. The
orbital parameters of such companions are consistent with recent calculations
which show that the migration process can induce the formation of low mass
planets external to the orbits of hot Jupiters. Systems with inflated planets
are therefore good targets in the search for terrestrial planets.Comment: 25 pages, 19 figures. Accepted for publication in MNRA
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