2,110 research outputs found
Inflating and Deflating Hot Jupiters: Coupled Tidal and Thermal Evolution of Known Transiting Planets
We examine the radius evolution of close-in giant planets with a planet
evolution model that couples the orbital-tidal and thermal evolution. For 45
transiting systems, we compute a large grid of cooling/contraction paths
forward in time, starting from a large phase space of initial semi-major axes
and eccentricities. Given observational constraints at the current time for a
given planet (semi-major axis, eccentricity, and system age) we find possible
evolutionary paths that match these constraints, and compare the calculated
radii to observations. We find that tidal evolution has two effects. First,
planets start their evolution at larger semi-major axis, allowing them to
contract more efficiently at earlier times. Second, tidal heating can
significantly inflate the radius when the orbit is being circularized, but this
effect on the radius is short-lived thereafter. Often circularization of the
orbit is proceeded by a long period while the semi-major axis slowly decreases.
Some systems with previously unexplained large radii that we can reproduce with
our coupled model are HAT-P-7, HAT-P-9, WASP-10, and XO-4. This increases the
number of planets for which we can match the radius from 24 (of 45) to as many
as 35 for our standard case, but for some of these systems we are required to
be viewing them at a special time around the era of current radius inflation.
This is a concern for the viability of tidal inflation as a general mechanism
to explain most inflated radii. Also, large initial eccentricities would have
to be common. We also investigate the evolution of models that have a floor on
the eccentricity, as may be due to a perturber. In this scenario we match the
extremely large radius of WASP-12b. (Abridged)Comment: 18 pages, 14 figures, 2 tables, Accepted for publication in Ap
A Unified Theory for the Atmospheres of the Hot and Very Hot Jupiters: Two Classes of Irradiated Atmospheres
We highlight the importance of gaseous TiO and VO opacity on the highly
irradiated close-in giant planets. The atmospheres of these planets naturally
fall into two classes that are somewhat analogous to the M- and L-type dwarfs.
Those that are warm enough to have appreciable opacity due to TiO and VO gases
we term the ``pM Class'' planets, and those that are cooler we term ``pL
Class'' planets. We calculate model atmospheres for these planets, including
pressure-temperature profiles, spectra, and characteristic radiative time
constants. We show that pM Class planets have hot stratospheres 2000 K
and appear ``anomalously'' bright in the mid infrared secondary eclipse, as was
recently found for planets HD 149026b and HD 209458b. This class of planets
absorbs incident flux and emits thermal flux from high in their atmospheres.
Consequently, they will have large day/night temperature contrasts and
negligible phase shifts between orbital phase and thermal emission light
curves, because radiative timescales are much shorter than possible dynamical
timescales. The pL Class planets absorb incident flux deeper in the atmosphere
where atmospheric dynamics will more readily redistribute absorbed energy. This
will lead to cooler day sides, warmer night sides, and larger phase shifts in
thermal emission light curves. Around a Sun-like primary this boundary occurs
at 0.04-0.05 AU. The eccentric transiting planets HD 147506b and HD
17156b alternate between the classes. Thermal emission in the optical from pM
Class planets is significant red-ward of 400 nm, making these planets
attractive targets for optical detection. The difference in the observed
day/night contrast between ups Andromeda b (pM Class) and HD 189733b (pL Class)
is naturally explained in this scenario. (Abridged.)Comment: Accepted to the Astrophysical Journa
Effects of Helium Phase Separation on the Evolution of Giant Planets
We present the first models of Saturn and Jupiter to couple their evolution
to both a radiative-atmosphere grid and to high-pressure phase diagrams of
hydrogen with helium. The purpose of these models is to quantify the
evolutionary effects of helium phase separation in Saturn's deep interior. We
find that prior calculated phase diagrams in which Saturn's interior reaches a
region of predicted helium immiscibility do not allow enough energy release to
prolong Saturn's cooling to its known age and effective temperature. We explore
modifications to published phase diagrams that would lead to greater energy
release, and find a modified H-He phase diagram that is physically reasonable,
leads to the correct extension of Saturn's cooling, and predicts an atmospheric
helium mass fraction Y_atmos in agreement with recent estimates. We then expand
our inhomogeneous evolutionary models to show that hypothetical extrasolar
giant planets in the 0.15 to 3.0 Jupiter mass range may have T_effs 10-15 K
greater than one would predict with models that do not incorporate helium phase
separation.Comment: 4 pages. Contribution to 'The Search for Other Worlds', Oct 2003,
University of Marylan
Bayesian Analysis of Hot Jupiter Radius Anomalies: Evidence for Ohmic Dissipation?
The cause of hot Jupiter radius inflation, where giant planets with K are significantly larger than expected, is an open question and
the subject of many proposed explanations. Rather than examine these models
individually, this work seeks to characterize the anomalous heating as a
function of incident flux, , needed to inflate the population of
planets to their observed sizes. We then compare that result to theoretical
predictions for various models. We examine the population of about 300 giant
planets with well-determined masses and radii and apply thermal evolution and
Bayesian statistical models to infer the anomalous power as a function of
incident flux that best reproduces the observed radii. First, we observe that
the inflation of planets below about M=0.5 \;\rm{M}_\rm{J} appears very
different than their higher mass counterparts, perhaps as the result of mass
loss or an inefficient heating mechanism. As such, we exclude planets below
this threshold. Next, we show with strong significance that
increases with towards a maximum of at K, and then decreases as temperatures increase further, falling
to at T_\rm{eff}= 2500 K. This high-flux decrease in inflation
efficiency was predicted by the Ohmic dissipation model of giant planet
inflation but not other models. We also explicitly check the thermal tides
model and find that it predicts far more variance in radii than is observed.
Thus, our results provide evidence for the Ohmic dissipation model and a
functional form for that any future theories of hot Jupiter radii
can be tested against.Comment: 14 pages, 14 figures, accepted to The Astronomical Journal. This
revision revises the description of statistical methods for clarity, but the
conclusions remain the sam
Understanding the Mass-Radius Relation for Sub-Neptunes: Radius as a Proxy for Composition
Transiting planet surveys like Kepler have provided a wealth of information
on the distribution of planetary radii, particularly for the new populations of
super-Earth and sub-Neptune sized planets. In order to aid in the physical
interpretation of these radii, we compute model radii for low-mass rocky
planets with hydrogen-helium envelopes. We provide model radii for planets 1-20
Earth masses, with envelope fractions from 0.01-20%, levels of irradiation
0.1-1000x Earth's, and ages from 100 Myr to 10 Gyr. In addition we provide
simple analytic fits that summarize how radius depends on each of these
parameters. Most importantly, we show that at fixed composition, radii show
little dependence on mass for planets with more than ~1% of their mass in their
envelope. Consequently, planetary radius is to first order a proxy for
planetary composition for Neptune and sub-Neptune sized planets. We recast the
observed mass-radius relationship as a mass-composition relationship and
discuss it in light of traditional core accretion theory. We discuss the
transition from rocky super-Earths to sub-Neptune planets with large volatile
envelopes. We suggest 1.75 Earth radii as a physically motivated dividing line
between these two populations of planets. Finally, we discuss these results in
light of the observed radius occurrence distribution found by Kepler.Comment: 17 pages, 9 figures, 7 tables, submitted to Ap
Re-inflated Warm Jupiters Around Red Giants
Since the discovery of the first transiting hot Jupiters, models have sought
to explain the anomalously large radii of highly irradiated gas giants. We now
know that the size of hot Jupiter radius anomalies scales strongly with a
planet's level of irradiation and numerous models like tidal heating, ohmic
dissipation, and thermal tides have since been developed to help explain these
inflated radii. In general however, these models can be grouped into two broad
categories: 1) models that directly inflate planetary radii by depositing a
fraction of the incident irradiation into the interior and 2) models that
simply slow a planet's radiative cooling allowing it to retain more heat from
formation and thereby delay contraction. Here we present a new test to
distinguish between these two classes of models. Gas giants orbiting at
moderate orbital periods around post main sequence stars will experience
enormous increases their irradiation as their host stars move up the sub-giant
and red-giant branches. If hot Jupiter inflation works by depositing
irradiation into the planet's deep interiors then planetary radii should
increase in response to the increased irradiation. This means that otherwise
non-inflated gas giants at moderate orbital periods >10 days can re-inflate as
their host stars evolve. Here we explore the circumstances that can lead to the
creation of these "re-inflated" gas giants and examine how the existence or
absence of such planets can be used to place unique constraints of the physics
of the hot Jupiter inflation mechanism. Finally, we explore the prospects for
detecting this potentially important undiscovered population of planets.Comment: Accepted by ApJ. 8 Figures and 8 page
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