* Astronomy

“35% of the Giant Planets Could Form Planets Like the Earth in the Habitable Zone”

When planets were first found around other stars, the planets that were found—at least around stars like the sun - were giant planets; they were more like Jupiter than Earth, so they were many hundreds of times more massive than the Earth. instead of being rocky planets they were big balls of gas like Jupiter. They were found very close to their stars, maybe 10% or even less of the Earth’s Sun distance, and because of this they were called “hot Jupiters” because they were gas-like planets. When a few of these were found, people tried to study exactly how these planets would form. All of the models require them to form much further away from the star: it’s thought that they can’t form that close to the star, they actually form much further out, and then somehow they move in.

Read more

Title: The Extrasolar Planet Epsilon Eridani b - Orbit and Mass
Authors: G. Fritz Benedict, Barbara E. McArthur, George Gatewood, Edmund Nelan, William D. Cochran, Artie Hatzes, Michael Endl, Robert Wittenmyer, Sallie L. Baliunas, Gordon A. H. Walker, Stephenson Yang, Martin K¨urster, Sebastian Els, and Diane B. Paulson


Hubble Space Telescope (HST ) observations of the nearby (3.22 pc), K2 V star Epsilon Eridani have been combined with ground-based astrometric and radial velocity data to determine the mass of its known companion. We model the astrometric and radial velocity measurements simultaneously to obtain the parallax, proper motion, perturbation period, perturbation inclination, and perturbation size.
Because of the long period of the companion, Epsilon Eri b, we extend our astrometric coverage to a total of 14.94 years (including the three year span of the HST data) by including lower-precision ground-based astrometry from the Allegheny Multichannel Astrometric Photometer. Radial velocities now span 1980.8 – 2006.3. We obtain a perturbation period, P = 6.85 ± 0.03 yr, semi-major axis á = 1.88±0.20 mas, and inclination i = 30°.1 ± 3°.8. This inclination is consistent with a previously measured dust disk inclination, suggesting coplanarity. Assuming a primary mass M* = 0.83solarMasses, we obtain a companion mass M = 1.55 ± 0.24 MJup. Given the relatively young age of Epsilon Eri (~800 Myr), this accurate exoplanet mass and orbit can usefully inform future direct imaging attempts. We predict the next periastron at 2007.3 with a total separation, ñ = 0.“3 at position angle, p.a. = 27°. Orbit orientation and geometry dictate that Epsilon Eri b will appear brightest in reflected light very nearly at periastron. Radial velocities spanning over 25 years indicate an acceleration consistent with a Jupiter-mass object with a period in excess of 50 years, possibly responsible for one feature of the dust morphology, the inner cavity.

Read more (PDF)

Title: A Long-Period Jupiter-Mass Planet Orbiting the Nearby M Dwarf GJ849
Authors: R. Paul Butler, John A. Johnson, Geoffrey W. Marcy, Jason T. Wright, Steven S. Vogt, Debra A. Fischer

We report precise Doppler measurements of GJ849 (M3.5V) that reveal the presence of a planet with a minimum mass of 0.82 Mjup in a 5.16 year orbit. At a = 2.35 AU, GJ849b is the first planet discovered around an M dwarf to orbit beyond 0.21 AU, and is only the second Jupiter mass planet discovered around a star less massive than 0.5 Msun. This detection brings to 4 the number of M stars known to harbor planets. Based on the results of our survey of 1300 FGKM main--sequence stars we find that giant planets within 2.5 AU are ~3 times more common around GK stars than around M stars. Due to the GJ849's proximity of 8.8 pc, the planet's angular separation is 0."27, making this system a prime target for high--resolution imaging using adaptive optics and future space--borne missions such as the Space Interferometry Mission. We also find evidence of a linear trend in the velocity time series, which may be indicative of an additional planetary companion.

Read more (68kb, PDF)

NASA's Hubble Space Telescope has discovered 16 extrasolar planet candidates orbiting a variety of distant stars in the central region of our Milky Way galaxy.
The planet bonanza was uncovered during a Hubble survey, called the Sagittarius Window Eclipsing Extrasolar Planet Search (SWEEPS). Hubble looked farther than has ever successfully been searched for extrasolar planets. Hubble peered at 180,000 stars in the crowded central bulge of our galaxy 26,000 light-years away. That is one-quarter the diameter of the Milky Way's spiral disk. The results will appear in the Oct. 5 issue of the journal Nature.

Read more