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TOPIC: Extrasolar Planets


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RE: Extrasolar Planets
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Title: Expanding and Improving the Search for Habitable Worlds
Authors: Avi M. Mandell

This review focuses on recent results in advancing our understanding of the location and distribution of habitable exo-Earth environments. We first review the qualities that define a habitable planet/moon environment. We extend these concepts to potentially habitable environments in our own Solar System and the current and future searches for biomarkers there, focusing on the primary targets for future exploratory missions: Mars, Europa, and Enceladus. We examine our current knowledge on the types of planetary systems amenable to the formation of habitable planets, and review the current state of searches for extra-solar habitable planets as well as expected future improvements in sensitivity and preparations for the remote detection of the signatures of life outside our Solar System.

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Title: The composition of transiting giant extrasolar planets
Authors: Tristan Guillot (OCA)

In principle, the combined measurements of the mass and radius a giant exoplanet allow one to determine the relative fraction of hydrogen and helium and of heavy elements in the planet. However, uncertainties on the underlying physics imply that some known transiting planets appear anomalously large, and this generally prevent any firm conclusion when a planet is considered on an individual basis. On the basis of a sample of 9 transiting planets known at the time, Guillot et al. A&A 453, L21 (1996), concluded that all planets could be explained with the same set of hypotheses, either by large but plausible modifications of the equations of state, opacities, or by the addition of an energy source, probably related to the dissipation of kinetic energy by tides. On this basis, they concluded that the amount of heavy elements in close-in giant planets is correlated with the metallicity of the parent star. Furthermore they showed that planets around metal-rich stars can possess large amounts of heavy elements, up to 100 Earth masses. These results are confirmed by studying the present sample of 18 transiting planets with masses between that of Saturn and twice the mass of Jupiter.

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Title: A HET search for planets around evolved stars
Authors: Andrzej Niedzielski, Alex Wolszczan

 We present our ongoing survey of ~1000 GK-giants with the 9.2-m Hobby-Eberly Telescope in search for planets around evolved stars. The stars selected for this survey are brighter than 11 mag and are located in the section of the HR-diagram, which is approximately delimited by the main sequence, the instability strip, and the coronal dividing line. We use the High Resolution Spectrograph to obtain stellar spectra for radial velocity measurements with a 4-6 m/s precision. So far, the survey has discovered a planetary-mass companion to the K0-giant HD 17092, and it has produced a number of plausible planet candidates around other stars. Together with other similar efforts, our program provides information on planet formation around intermediate mass main sequence-progenitors and it will create the experimental basis with which to study dynamics of planetary systems around evolving stars.

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GD 66b
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GD 66b, extrasolar planet orbiting a white dwarf

Name GD 66
Distance 51 pc
Spectral Type DA
Apparent Magnitude V 15.6
Mass 0.64 solar masses
Effective Temperature 11980 K
RA. 05 20 38
Dec +30 48 24


Name GD 66 b
Mass 2.11 (± 0.14) Jupiter masses
Semi major axis 2.356 (± 0.081) AU
Orbital period 1650 (± 77) days
Eccentricity 0
Tmax VR 2452938.8846146 (± 2.8e-06)


GD66N3x

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RE: Extrasolar Planets
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Rocky extrasolar planets thought to be half frozen and half scorched might instead rock back and forth, creating large swaths of twilight with temperatures suitable for life.
Because of gravitational tugs with the objects they orbit, rocky bodies often settle into trajectories in which they always show the same face to their hosts. Such 'tidally locked' exoplanets would thus seem like bad candidates for life, since the hemisphere facing their host stars would roast and the dark side would freeze.
But a new computer model by Anthony Dobrovolskis of NASA Ames Research Center in California, US, suggests this is not always so. He finds that such planets can rock to and fro if they travel on elongated, or eccentric orbits, creating a 'twilight zone' that could be hospitable to life.
The Moon experiences a similar rocking motion. It always shows the same face to Earth, taking the same amount of time to rotate around its axis as it does to circle our planet once. However, because the Moon's path around the Earth is not perfectly circular, its orbital speed is sometimes faster or slower than its rotational speed. The difference between the two motions causes the Moon to rock slightly.

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Title: Tidal friction in close-in satellites and exoplanets. The Darwin theory re-visited
Authors: Sylvio Ferraz-Mello (1), Adrián Rodríguez (1), Hauke Hussmann (2) ((1) Instituto de Astronomia Geofísica e Ciências Atmosféricas. Universidade de São Paulo, Brasil, (2) Institut für Planetenforschung, DLR, Berlin-Adlershof, Germany)

This report is a review of Darwin's classical theory of bodily tides in which are given the analytical expressions for the orbital and rotational evolution of the bodies and for the energy dissipation rates due to their tidal interaction. It is shown that almost all results found in the literature for the study of evolution due to tidal friction can be straightforwardly derived from Darwin's theory. General formulas are given which do not depend on any assumption linking the tidal lags to the frequencies of the corresponding tidal waves (except that equal frequency harmonics are assumed to span equal lags). The general formulas are applied to several physical scenarios including both fast and slow rotating central bodies as well as their companions. Emphasis is given on the case of companions having reached one of the two possible final states: capture into a 1:1 spin-orbit resonance (synchronisation) or the super-synchronous stationary rotation resulting from the vanishing of the average tidal torque. The true synchronisation with non-zero eccentricity is only possible if an extra torque exists opposite to the tidal torque. The theory is developed assuming that this additional torque is produced by an equatorial permanent asymmetry in the companion. The indirect tidal effects and some non-tidal effects due to that asymmetry are considered. The theory is developed only to the second degree in eccentricity and inclination (obliquity), but can easily be extended to higher orders.

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Planetary scientists at UCL have identified the point at which a star causes the atmosphere of an orbiting gas giant to become critically unstable, as reported in this week's Nature (December 6). Depending upon their proximity to a host star, giant Jupiter-like planets have atmospheres which are either stable and thin, or unstable and rapidly expanding. This new research enables us to work out whether planets in other systems are stable or unstable by using a three dimensional model to characterise their upper atmospheres.

"We know that Jupiter has a thin, stable atmosphere and orbits the Sun at five Astronomical Units (AU) - or five times the distance between the Sun and the Earth. In contrast, we also know that closely orbiting exoplanets like HD209458b - which orbits about 100 times closer to its sun than Jupiter does - has a very expanded atmosphere which is boiling off into space. Our team wanted to find out at what point this change takes place, and how it happens. Our paper shows that if you brought Jupiter inside the Earth's orbit, to 0.16AU, it would remain Jupiter-like, with a stable atmosphere. But if you brought it just a little bit closer to the Sun, to 0.14AU, its atmosphere would suddenly start to expand, become unstable and escape. This dramatic change takes place because the cooling mechanism that we identified breaks down, leading to the atmosphere around the planet heating up uncontrollably" - Tommi Koskinen of UCL's Physics and Astronomy Department, and lead author of the paper.

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Hot Jupiters
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Gas giant planets can get twice as close to their stars as Mercury is to the Sun without evaporating, a new computer simulation suggests. The work suggests the 'hot Jupiters' discovered on tight orbits around their stars are in no immediate danger of boiling away into space.
Many gas giants have been found very close to their parent stars a handful even lie less than 6% of Mercury's distance from the Sun. But it has never been clear just how close planets could get without heating up so much that their atmospheres would start escaping or "evaporating" into space.
A new study suggests this threshold lies more than twice as close as Mercury's distance to the Sun (or about 0.15 astronomical units, where 1 AU is the distance between the Earth and the Sun). Tommi Koskinen of University College London, UK, led the team that carried out the study.
The outermost layer of a planet's atmosphere is where the action is as far as evaporation is concerned. The star blasts this layer with ultraviolet light and X-rays, which heat it up. The atmosphere can stay cool and avoid evaporating if it can radiate enough energy back into space in the form of infrared light.
To see how the balance between these two effects shifted with distance from the star, Koskinen's team created a 3D computer simulation of the upper atmosphere of a planet with the mass of Jupiter orbiting a Sun-like star. They found that evaporation did not occur until the planet was within about 40% of Mercury's distance from the Sun about twice as close as a previous estimate.

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HD23514
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Astronomers using the Gemini North telescope on Mauna Kea believe they have found the telltale sign of rocky, Earth-like planets around a sunlike star about 400 light-years away in the Pleiades star cluster, Gemini officials announced.
That telltale clue is a large amount of hot dust circling an "adolescent" star with the designation HD23514.

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