* Astronomy

Comet 81P/Wild is at Opposition (3.480 AU) on the 24th October 2014 

Ephemeris

Date    TT    R. A. (2000) Decl.     Delta      r    Elong.  Phase   Mag
2014 10 23    02 00 38.8 +08 01 03   3.4830  4.4759   175.7     1.0  19.5  23.1
2014 10 24    01 59 56.8 +07 57 05   3.4798  4.4727   176.0     0.9  19.5  23.1
2014 10 25    01 59 14.8 +07 53 08   3.4769  4.4695   175.9     0.9  19.5  23.1
2014 10 26    01 58 32.6 +07 49 11   3.4744  4.4663   175.5     1.0  19.5  23.1
2014 10 27    01 57 50.4 +07 45 14   3.4721  4.4631   174.9     1.1  19.4  23.1
2014 10 28    01 57 08.3 +07 41 19   3.4702  4.4598   174.1     1.3  19.4  23.1
2014 10 29    01 56 26.1 +07 37 25   3.4686  4.4566   173.2     1.5  19.4  23.1
2014 10 30    01 55 44.0 +07 33 32   3.4673  4.4534   172.2     1.7  19.4  23.2
2014 10 31    01 55 02.1 +07 29 41   3.4664  4.4501   171.1     2.0  19.4  23.2

Title: The origin of the 3.4 micron feature in Wild 2 cometary particles and in ultracarbonaceous interplanetary dust particles
Authors: Graciela Matrajt, George Flynn, Don Brownlee, Dave Joswiak, Sasa Bajt

We analysed 2 ultra-carbonaceous interplanetary dust particles and 2 cometary Wild 2 particles with infrared spectroscopy. We characterised the carrier of the 3.4 micron band in these samples and compared its profile and the CH2/CH3 ratios to the 3.4 micron band in the diffuse interstellar medium (DISM), in the insoluble organic matter (IOM) from 3 primitive meteorites, in asteroid 24 Themis and in the coma of comet 103P/Hartley 2. We found that the 3.4 micron band in both Wild 2 and IDPs is similar, but different from all the other astrophysical environments that we compared to. The 3.4 micron band in IDPs and Wild 2 particles is dominated by CH2 groups, the peaks are narrower and stronger than in the meteorites, asteroid Themis, and the DISM. Also, the presence of the carbonyl group C=O at 1700 cm-1 (5.8 micron) in most of the spectra of our samples, indicates that these aliphatic chains have O bonded to them, which is quite different from astronomical spectra of the DISM. Based on all these observations we conclude that the origin of the carrier of the 3.4 micron band in IDPs and Wild 2 samples is not interstellar, instead, we suggest that the origin lies in the outermost parts of the solar nebula.

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UH scientists analyse comet grain to estimate age of Jupiter

Jupiter ploughs through the solar system like a giant vacuum cleaner, sucking up rocks and dust with its massive gravity.
That's been going on for about 4.565 billion years, University of Hawaii scientists reckon by studying a grain of comet dust.
Particles from Comet Wild 2 were brought back to Earth by NASA's Stardust spacecraft in 2006. One was a fragment formed by high-temperature processes in the cloud that surrounded the sun in its infancy.
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Shooting Iron Sulphides into Aluminium Foil to Better Understand Comet Wild 2

When NASA's Stardust mission returned samples from comet 81P/Wild 2 to Earth in 2006, researchers found particles in the aerogel collector-cells as well as in the aluminium (Al) foil, which wrapped the cells and facilitated the safe removal of the aerogel from the collector frame. These Al-foil pull tabs, though not the primary collecting material, captured a bonus assortment of cometary grains. But did the impacts into the Al foil change the Wild 2 grains? Teams of scientists have been hard at work in the laboratory to answer that question by simulating impacts into Stardust Al foil using a light gas gun to shoot powders of the major minerals found in cometary dust.
They are studying the impact craters on the Al foils and what's left of the impacting particles, the residues, that coat the crater surfaces. Whether or not the original chemical composition of the impacting particle is preserved in the residue is a key question to examine in the laboratory, as the answer bears on how accurately the researchers can determine the original chemistry of the cometary grains from Wild 2.
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