* Astronomy

 Our solar system started out as a star at the centre of a vast, disk-shaped nebula of dust and gas. By conventional thinking, the extreme heat near the sun could melt dust and form new minerals, but all of these high-temperature minerals could only drift inward toward the sun, not outward. That led to different types of minerals in the inner and outer reaches of the nebula. But the Stardust spacecraft threw a wrench in this theory by returning high-temperature minerals to Earth from comet Wild 2.
Planetary scientist Fred Ciesla of the Carnegie Institution of Washington's Department of Terrestrial Magnetism in Washington, D.C., thinks he's found a solution to the conundrum. For computational simplicity, past modelling treated the nebula as a one-dimensional object. In such simulations, all gas and dust is assumed to behave the same way, whether it is near the nebula core or far above or below its midplane. But Ciesla performed more computationally demanding, two-dimensional simulations. In these, most nebular material still flows inward toward the sun; but near the midplane, the inward flow ceases or even reverses, letting the outward diffusion of material to the comet-forming region proceed. Ciesla presents his findings in the 26 October issue of Science.

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One of the most remarkable particles found in the Stardust collection is a particle named after the Inca Sun God Inti. Inti is collection of rock fragments that are all related in mineralogical, isotopic and chemical composition to rare components in meteorites called "Calcium Aluminium Inclusions" or CAI's for short. CAI's are the oldest materials that formed in the solar system and they contain a remarkable set of minerals that form at extremely high temperature. In addition to these same minerals, Inti also has tiny inclusions that may have been the first generation of solids to condense from hot gas in the early solar system. These include compounds of titanium, vanadium and nitrogen (TiN and VN) as well as tiny nuggets of platinum, osmium, ruthenium, tungsten and molybdenum. In certain chemical environments and at high enough temperature in the early solar system these exotic materials were the only solid materials that could survive without being vaporised.

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Astronomers have observed neon in disks of dust and gas swirling around sunlike stars for the first time.
University of Arizona astronomers who collaborated in the observations say that neon could show which stars retain their surrounding dust-and-gas disks needed to form planets and which stars might already have formed planets.

"When I saw the neon, I couldn't believe it. I was just amazed. We were not expecting to see neon around low-mass stars like our sun" - Astronomer Ilaria Pascucci, University Arizona Steward Observatory.

Pascucci is a co-investigator on a Spitzer Space Telescope Legacy project called "Formation and Evolution of Planetary Systems, known as FEPS, headed by Steward Observatory's Michael R. Meyer. The project used an infrared spectrometer to conduct a sensitive search for planet-forming gas around 35 young, solar analogue stars.
Neon showed up in disks of four sunlike stars in Spitzer's FEPS data. The discovery was a surprise because "we didn't realise that solar analogue stars could radiate enough high-energy (X-ray and ultraviolet) light to ionise neon".

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Title: The Formation of the Oort Cloud in Open Cluster Environments
Authors: Nathan A. Kaib, Thomas Quinn
(Version v2)

We study the influence of the initial stellar environment on the formation and current structure of the Oort cloud. To do this, we have run four different simulations of the formation of the Oort Cloud for 4.5 Gyrs, each containing 20,000 particles. In each simulation, the solar system spends its first 100 Myrs in a different open cluster environment before transitioning to its current field environment. We find that, compared to forming in the field environment, the inner Oort Cloud is preferentially loaded with comets while the Sun resides in the open cluster and that most of this material remains locked in the interior of the cloud for the next 4.4 Gyrs. On the other hand, the outer portions of the Oort Cloud in each of the simulations are all similar. Depending on the initial stellar density of the cluster environment, the internal structure of the present day Oort Cloud will vary widely.

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Solar system bodies arranged from large to small
This is an interesting illustration of bodies in our Solar system which are larger than 200 miles (322 km) in diameter. They are laid out from the largest to the smallest.

IMAGE (40kb, 1600 x 145)

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