* Astronomy

The powerful vision of NASA's Hubble Space Telescope has allowed astronomers to study for the first time the layer-cake structure of the atmosphere of a planet orbiting another star. Hubble discovered a dense upper layer of hot hydrogen gas where the super-hot planet's atmosphere is bleeding off into space.
This is an artist's illustration of the extrasolar planet, designated HD 209458b, which is unlike any world in our solar system. It completes an orbit around its host star every 3.5 days. It is about the size of Jupiter. Unlike Jupiter, HD 290458b is so hot that its atmosphere is "puffed up." Starlight is heating the planet's atmosphere, causing hot gas to escape into space. Astronomers used Hubble to analyse the starlight that filtered through the planet's atmosphere. Imprinted on the starlight is information about the atmosphere's structure and chemical makeup.

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Title: HD 97048's Circumstellar Environment as Revealed by a HST/ACS Coronagraphic Study of Disk Candidate Stars
Authors: R. L. Doering, M. Meixner, S. T. Holfeltz, J. E. Krist, D. R. Ardila, I. Kamp, M. C. Clampin, S. H. Lubow

We present the results of a coronagraphic scattered-light imaging survey of six young disk candidate stars using the Hubble Space Telescope Advanced Camera for Surveys. The observations made use of the 1.8" occulting spot through the F606W (broad V) filter. Circumstellar material was imaged around HD 97048, a Herbig Ae/Be star located in the Chamaeleon I dark cloud at a distance of 180 pc. The material is seen between ~2" (360 AU) and ~4" (720 AU) from the star in all directions. A V-band azimuthally-averaged radial surface brightness profile peaks at r = 2" with a value of 19.6 ± 0.2 mag arcsec^-2 and smoothly decreases with projected distance from the star as r^(-3.3 ± 0.5). An integrated flux of 16.8 ± 0.1 mag is measured between 2" and 4", corresponding to a scattered-light fractional luminosity lower limit of 8.4 x 10^-4. Filamentary structure resembling spiral arms similar to that seen in Herbig Ae/Be disks is observed. Such structure has been attributed to the influence of orbiting planets or stellar encounters. Average surface brightness upper limits are determined for the five non-detections: HD 34282, HD 139450, HD 158643, HD 159492, and HD 195627. Possible reasons for the non-detections are disks that are too faint or disks hidden by the occulter.

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Title: Terrestrial Planet Formation Around Individual Stars Within Binary Star Systems
Authors: Elisa V. Quintana (NASA ARC), Fred C. Adams (U. Michigan), Jack J. Lissauer (NASA ARC), John E. Chambers (Carnegie/DTM)

We calculate herein the late stages of terrestrial planet accumulation around a solar type star that has a binary companion with semimajor axis larger than the terrestrial planet region. We perform more than one hundred simulations to survey binary parameter space and to account for sensitive dependence on initial conditions in these dynamical systems. As expected, sufficiently wide binaries leave the planet formation process largely unaffected. As a rough approximation, binary stars with periastron q_B > 10 AU have minimal effect on terrestrial planet formation within ~2 AU of the primary, whereas binary stars with q_B \la 5 AU restrict terrestrial planet formation to within ~ 1 AU of the primary star. Given the observed distribution of binary orbital elements for solar type primaries, we estimate that about 40 -- 50 percent of the binary population is wide enough to allow terrestrial planet formation to take place unimpeded. The large number of simulations allows for us to determine the distribution of results -- the distribution of plausible terrestrial planet systems -- for effectively equivalent starting conditions. We present (rough) distributions for the number of planets, their masses, and their orbital elements.

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They are out there, and they are unlike anything previously discovered in the galaxy. Dubbed "super-Earths" because of their size, these planets are the first predominantly rocky worlds found outside our solar system.
Big deal? You bet. The discovery of this new class of planet takes us a significant step closer to finding other Earth-like worlds that might be suitable for life. It also sheds new light on the physics of planetary formation. Indeed, the race to find Earth's bigger cousins is hotting up: a French-led space telescope called Corot is scheduled to launch later this month, with the promise of detecting more of these mysterious worlds.
What is most interesting is not that super-Earths are big, but that they are relatively small. Since the discovery in 1995 of a Jupiter-sized planet around the star 51 Pegasi, astronomers have located more than 200 extrasolar planets.

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