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TOPIC: Extrasolar Planets


L

Posts: 131433
Date:
TrES-3
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Title: TrES-3: A Nearby, Massive, Transiting Hot Jupiter in a 31-Hour Orbit
Authors: Francis T. O'Donovan, David Charbonneau, Gáspár Á. Bakos, Georgi Mandushev, Edward W. Dunham, Timothy M. Brown, David W. Latham, Guillermo Torres, Alessandro Sozzetti, Géza Kovács, Mark E. Everett, Nairn Baliber, Márton G. Hidas, Gilbert A. Esquerdo, Markus Rabus, Hans J. Deeg, Juan A. Belmonte, Lynne A. Hillenbrand, Robert P. Stefanik.

We describe the discovery of a massive transiting hot Jupiter with a very short orbital period (1.30619 d), which we name TrES-3. From spectroscopy of the host star GSC 03089-00929, we measure T_eff = 5720 ± 150 K, logg=4.6 ± 0.3, and vsini < 2 km/s, and derive a stellar mass of 0.90 ± 0.15 M_sun. We estimate a planetary mass of 1.92 ± 0.23 M_Jup, based on the sinusoidal variation of our high-precision radial velocity measurements. This variation has a period and phase consistent with our transit photometry. Our spectra show no evidence of line bisector variations that would indicate a blended eclipsing binary star. From detailed modelling of our B and z photometry of the 2.5%-deep transits, we determine a stellar radius 0.802 ± 0.046 R_sun and a planetary radius 1.295 ± 0.081 R_Jup. TrES-3 has one of the shortest orbital periods of the known transiting exoplanets, facilitating studies of orbital decay and mass loss due to evaporation, and making it an excellent target for future studies of infrared emission and reflected starlight.

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Posts: 131433
Date:
TrES Exoplanets
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Title: TrES Exoplanets and False Positives: Finding the Needle in the Haystack
Authors: Francis T. O'Donovan, David Charbonneau

Our incomplete understanding of the formation of gas giants and of their mass-radius relationship has motivated ground-based, wide-field surveys for new transiting extrasolar giant planets. Yet, astrophysical false positives have dominated the yield from these campaigns. Astronomical systems where the light from a faint eclipsing binary and a bright star is blended, producing a transit-like light curve, are particularly difficult to eliminate. As part of the Trans-Atlantic Exoplanet Survey, we have encountered numerous false positives and have developed a procedure to reject them. We present examples of these false positives, including the blended system GSC 03885-00829 which we showed to be a K dwarf binary system superimposed on a late F dwarf star. This transit candidate in particular demonstrates the careful analysis required to identify astrophysical false positives in a transit survey. From amongst these impostors, we have found two transiting planets. We discuss our follow-up observations of TrES-2, the first transiting planet in the Kepler field.

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Posts: 131433
Date:
HD 33636
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Title: The Mass of the Candidate Exoplanet Companion to HD 33636 from Hubble Space Telescope Astrometry and High-Precision Radial Velocities
Authors: Jacob L. Bean, Barbara E. McArthur, G. Fritz Benedict, Thomas E. Harrison, Dmitry Bizyaev, Edmund Nelan, Verne V. Smith

We have determined a dynamical mass for the companion to HD 33636 which indicates it is a low-mass star instead of an exoplanet. Our result is based on an analysis of Hubble Space Telescope (HST) astrometry and ground-based radial velocity data. We have obtained high-cadence radial velocity measurements spanning 1.3 years of HD 33636 with the Hobby-Eberly Telescope at McDonald Observatory. We combined these data with previously published velocities to create a data set that spans nine years. We used this data set to search for, and place mass limits on, the existence of additional companions in the HD 33636 system. Our high-precision astrometric observations of the system with the HST Fine Guidance Sensor 1r span 1.2 years. We simultaneously modelled the radial velocity and astrometry data to determine the parallax, proper motion, and perturbation orbit parameters of HD 33636. Our derived parallax, pi = 35.6 ± 0.2 mas, agrees within the uncertainties with the Hipparcos value. We find a perturbation period P = 2117.3 ± 0.8 days, semimajor axis a_A = 14.2 ± 0.2 mas, and system inclination i = 4.1 ± 0.1 deg. Assuming the mass of the primary star M_A = 1.02 ± 0.03 M_sun, we obtain a companion mass M_B = 142 ± 11 M_jup = 0.14 ± 0.01 M_sun. The much larger true mass of the companion relative to its minimum mass estimated from the spectroscopic orbit parameters (M sin i = 9.3 M_jup) is due to the near face-on orbit orientation. This result demonstrates the value of follow-up astrometric observations to determine the true masses of exoplanet candidates detected with the radial velocity method.

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L

Posts: 131433
Date:
14 Herculis
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Title: A dynamical analysis of the 14 Her planetary system
Authors: K. Gozdziewski, C. Migaszewski, M. Konacki

Precision radial velocity (RV) measurements of the Sun-like dwarf 14 Herculis in Naef et. al (2004), Butler et. al (2006) and Wittenmyer et al (2007) reveal a Jovian planet in a 1700 day orbit and a trend indicating the second distant object. On the grounds of dynamical considerations, we test a hypothesis that the trend can be explained by the presence of an additional giant planet. We derive dynamical limits to th orbital parameters of the putative outer Jovian companion in an orbit within ~12AU. In this case, the mutual interactions between the Jovian planets are important for the long-term stability of the system. Hence the kinematic model is not adequate to model the RV data. The best self-consistent and stable Newtonian fit corresponds to an edge-on configuration of Jovian planets in about 9AU orbit with a moderate eccentricity ~0.2 and confined to a zone spanned by the low-order mean motion resonances 5:1 and 6:1. This solution lies in a shallow minimum of Chi2 and persists over a wide range of the system inclination. Because the data cover roughly a half of the period (~27 yr) of the orbital solution, the semi-major axis of the outer planet cannot be well constrained. Other stable configurations within 1\sigma confidence interval of the best fit are possible and correspond to the semi-major axis of the outer planet in the range of (6,12) AU. The orbital inclination cannot yet be determined but when it decreases, both planetary masses approach ~10m_J and for i ~30 deg the hierarchy of the masses is reversed. Simultaneously, the border of dynamical stability is shifted beyond 8--9~AU.

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L

Posts: 131433
Date:
RE: Extrasolar Planets
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The hot, the fat and the molten.
The past few weeks have been feverishly active for planetary scientists record-breaking results have popped out in all directions.
The glut of planetary announcements is probably coincidental, says Scott Gaudi, an astronomer studying exoplanets at Ohio State University in Columbus, but it might be because the transit method watching planets as they pass in front of their stars is reaching maturity.
But hot-planet hunter Joseph Harrington from the University of Central Florida in Orlando suggests that researchers are racing to publish their papers or submit grant proposals before this year's application deadline for time on the Spitzer space telescope. And Gáspár Bakos at the Harvard Smithsonian Centre for Astrophysics in Cambridge, Massachusetts, suggests that gossip in the community may have prompted everyone to make their announcements at the same time.

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L

Posts: 131433
Date:
HD 155358
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Name HD 155358
Distance 42.7 (± 1.3) pc  
Spectral Type G0    
Apparent Magnitude V = 7.5    
Mass 0.87 (± 0.07) Msun   
Age 10 Gyr   
Effective Temperature 5760 (± 101) K   
Metallicity [Fe/H] -0.68 (± 0.07)     
Right Asc. Coord. 17 09 35    
Decl. Coord. +33 21 21    
 
 
NameHD 155358 bHD 155358 c
Discovered in 2007 2007
Mass 0.89 (± 0.12) MJ   0.504 (± 0.075) MJ  
Semi major axis 0.628 (± 0.02) AU   1.224 (± 0.081) AU  
Orbital period 195 (± 1.1) days   530.3 (± 27.2) days  
Eccentricity 0.112 (± 0.037)   0.176 (± 0.174)  
Omega 162 (± 20) deg.   279 (± 38) deg.  
Tperi 2453950 (± 10.4)   2454420.3 (± 79.3)  
 
 

Source



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L

Posts: 131433
Date:
HD 189733b
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L

Posts: 131433
Date:
WASP-1
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Title: WASP-1: A lithium- and metal-rich star with an oversized planet
Authors: H.C. Stempels, A. Collier Cameron, L. Hebb, B. Smalley, S. Frandsen

In this paper we present our results of a comprehensive spectroscopicanalysis of WASP-1, the host star to the exoplanet WASP-1b. We derive T_eff = 6110 ± 45 K, log g = 4.28 ± 0.15, and [M/H] = 0.23 ± 0.08, and also a high abundance of lithium, log n(Li) = 2.91 ± 0.05. These parameters suggests an age for the system of 1-3 Gyr and a stellar mass of 1.25-1.35 M_sun. This means that WASP-1 has properties very similar to those of HD 149026, the host star for the highest density planet yet detected. Moreover, their planets orbit at comparable distances and receive comparable irradiating fluxes from their host stars. However, despite the similarity of WASP-1 with HD 149026, their planets have strongly different densities. This suggests that gas-giant planet density is not a simple function of host-star metallicity or of radiation environment at ages of ~2 Gyr.

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L

Posts: 131433
Date:
40 Eridani A
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Science fiction may soon become science fact.
Astronomers at NASA's Jet Propulsion Laboratory have recently concluded that the upcoming planet-finding mission, SIM PlanetQuest, would be able to detect an Earth-like planet around the star 40 Eridani, a planet familiar to "Star Trek" fans as "Vulcan." 40 Eridani, a triple-star system 16 light-years from Earth, includes a red-orange K dwarf star slightly smaller and cooler than our sun. Vulcan is thought to orbit that dwarf star, called 40 Eridani A.  

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L

Posts: 131433
Date:
RE: Extrasolar Planets
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Researchers using NASA's Spitzer Space Telescope have learned what the weather is like on two distant, exotic worlds. One team of astronomers used the infrared telescope to map temperature variations over the surface of a giant gas planet, HD 189733b, revealing it likely is whipped by roaring winds. Another team determined that the gas planet HD 149026b is the hottest yet discovered. Both findings appear May 9 in Nature.

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