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Circumstellar space: Where chemistry happens for the very first time
August 01, 2007Picture a cool place, teeming with a multitude of hot bodies twirling about in rapidly changing formations of singles and couples, partners and groups, constantly dissolving and reforming.
If you were thinking of the dance floor in a modern nightclub, think again.
It's a description of the shells around dying stars, the place where newly formed elements make compounds and life takes off, said Katharina Lodders, Ph.D., research associate professor of earth and planetary sciences in Arts & Sciences at Washington University in St. Louis.
Chemistry for the very first time
"The circumstellar environment is where chemistry happens for the very first time," said Lodders. "It's the first place a newly synthesized element can do chemistry. It's a supermarket of things from dust to gas and dust grains to molecules and atoms. The circumstellar shells enable a chemistry that produced grains older than our sun itself. It's generated some popular interest, and this year marks the 20th anniversary of the presolar grain discoveries."
After the discovery of presolar diamonds in a meteorite in 1987 -- the first stardust found in a meteorite -- researchers at Washington University in St. Louis have been prominent in finding and analyzing pre-solar grains made of silicon carbide, diamonds, corundum, spinel, and silicates. The latest discovery -- a silicate grain that formed around a foreign star and became incorporated into a comet in our solar system -- was captured and returned by the STARDUST space mission in 2006.
Lodders said that nucleosynthesis -- the creation of atoms -- takes place in a star's interior, made of a plasma far too hot for any molecular chemistry to take place. The event that enables chemistry is the death of a star, when elements are spewed out of the core, creating a shell around the star. As this circumstellar shell cools, the elements react to form gas molecules and solid compounds.
A star comes of age
Our sun and other dwarf stars of less than about ten solar masses burn hydrogen into helium in their cores. As they come of age, they become Red Giant stars and burn the helium to carbon and oxygen. But many heavy elements such as strontium and barium, even heavier than iron, are also produced, albeit in much smaller quantities than carbon. At the same time, the star begins to eject its outer layers into the interstellar medium by stellar winds, building up a circumstellar shell. So eventually, most of a star's mass, including the newly produced elements, is ejected into the interstellar medium through the circumstellar shell. Most interstellar grains come from such stars.
Heavyweight stars go out more spectacularly, in violent supernovae such as SN2006gy, first observed late last year, which has turned out to be the most massive supernova ever witnessed. But no matter what, all stars like the sun and heavier ones like SN2006gy empty their elements into their circumstellar environments, where gaseous compounds and grains can form. From there, the gas and grains enter the interstellar medium and provide the material for new stars and solar systems to be born.
Lodders presented a paper on circumstellar chemistry and presolar grains at the 233rd American Chemical Society National Meeting, held March 25-29 in Chicago, where a special symposium was held to track the evolution of the elements across space and time. A book of proceedings is being prepared for publication.
Lodders said that just one percent of all known presolar grains come from supernovas. She said that several million stars have been catalogued and several thousand individual presolar grains have now been analyzed.
"Back in the 1960s, astronomers didn't know that presolar grains existed in meteorites," Lodders said. "They were discovered when researchers were looking at meteorite samples and studying noble gases. They asked what is the mineral carrier of the noble gases."
By separating minerals from samples of meteorites, they eventually found the carriers of the noble gases -- presolar diamonds, graphite and silicon carbide -- and thus started the study of presolar grains 20 years ago.
"So the genuine, micron-size star dust survived despite the potential chemical and physical processing in the interstellar medium, during solar system formation, and in the meteorite's parent asteroid," she said. "Since the star dust preserved in meteorites must have been already present before the solar system and the meteorites formed, researchers call this star dust presolar grains."
"Laboratory astronomy of stardust has revealed much about stellar element and isotope production, and about gas and dust formation conditions in giant stars and supernovae."
Washington University in St. Louis
Chemistry for the very first time
"The circumstellar environment is where chemistry happens for the very first time," said Lodders. "It's the first place a newly synthesized element can do chemistry. It's a supermarket of things from dust to gas and dust grains to molecules and atoms. The circumstellar shells enable a chemistry that produced grains older than our sun itself. It's generated some popular interest, and this year marks the 20th anniversary of the presolar grain discoveries."
After the discovery of presolar diamonds in a meteorite in 1987 -- the first stardust found in a meteorite -- researchers at Washington University in St. Louis have been prominent in finding and analyzing pre-solar grains made of silicon carbide, diamonds, corundum, spinel, and silicates. The latest discovery -- a silicate grain that formed around a foreign star and became incorporated into a comet in our solar system -- was captured and returned by the STARDUST space mission in 2006.
Lodders said that nucleosynthesis -- the creation of atoms -- takes place in a star's interior, made of a plasma far too hot for any molecular chemistry to take place. The event that enables chemistry is the death of a star, when elements are spewed out of the core, creating a shell around the star. As this circumstellar shell cools, the elements react to form gas molecules and solid compounds.
A star comes of age
Our sun and other dwarf stars of less than about ten solar masses burn hydrogen into helium in their cores. As they come of age, they become Red Giant stars and burn the helium to carbon and oxygen. But many heavy elements such as strontium and barium, even heavier than iron, are also produced, albeit in much smaller quantities than carbon. At the same time, the star begins to eject its outer layers into the interstellar medium by stellar winds, building up a circumstellar shell. So eventually, most of a star's mass, including the newly produced elements, is ejected into the interstellar medium through the circumstellar shell. Most interstellar grains come from such stars.
Heavyweight stars go out more spectacularly, in violent supernovae such as SN2006gy, first observed late last year, which has turned out to be the most massive supernova ever witnessed. But no matter what, all stars like the sun and heavier ones like SN2006gy empty their elements into their circumstellar environments, where gaseous compounds and grains can form. From there, the gas and grains enter the interstellar medium and provide the material for new stars and solar systems to be born.
Lodders presented a paper on circumstellar chemistry and presolar grains at the 233rd American Chemical Society National Meeting, held March 25-29 in Chicago, where a special symposium was held to track the evolution of the elements across space and time. A book of proceedings is being prepared for publication.
Lodders said that just one percent of all known presolar grains come from supernovas. She said that several million stars have been catalogued and several thousand individual presolar grains have now been analyzed.
"Back in the 1960s, astronomers didn't know that presolar grains existed in meteorites," Lodders said. "They were discovered when researchers were looking at meteorite samples and studying noble gases. They asked what is the mineral carrier of the noble gases."
By separating minerals from samples of meteorites, they eventually found the carriers of the noble gases -- presolar diamonds, graphite and silicon carbide -- and thus started the study of presolar grains 20 years ago.
"So the genuine, micron-size star dust survived despite the potential chemical and physical processing in the interstellar medium, during solar system formation, and in the meteorite's parent asteroid," she said. "Since the star dust preserved in meteorites must have been already present before the solar system and the meteorites formed, researchers call this star dust presolar grains."
"Laboratory astronomy of stardust has revealed much about stellar element and isotope production, and about gas and dust formation conditions in giant stars and supernovae."
Washington University in St. Louis
Circumstellar Current Events and Circumstellar News RSSSharpest views of Betelgeuse reveal how supergiant stars lose mass
Using different state-of-the-art techniques on ESO's Very Large Telescope, two independent teams of astronomers have obtained the sharpest ever views of the supergiant star Betelgeuse.
Radio telescope images reveal planet-forming disk orbiting twin suns
Astronomers are announcing today that a sequence of images collected with the Smithsonian's Submillimeter Array (SMA) clearly reveals the presence of a rotating molecular disk orbiting the young binary star system V4046 Sagittarii.
Jupiter-like Planets Could Form Around Twin Suns
Life on a planet ruled by two suns might be a little complicated. Two sunrises, two sunsets. Twice the radiation field.
Universally Speaking, Earthlings Share a Nice Neighborhood
We don't have spacecraft to take us outside our solar system--not yet, at least. Still, astronomers thought they had a pretty good understanding of how our solar system formed and in turn, how others formed.
A Planet in Progress?
Scientists are one step closer to understanding how new planets form, thanks to research funded by the National Science Foundation (NSF) and carried out by a team of astrophysicists at the American Museum of Natural History.
Astronomers find stellar cradle where planets form
Astronomers at the University of Illinois have found the first clear evidence for a cradle in space where planets and moons form.
APL Astronomer Spies Conditions 'Just Right' for Building an Earth
An Earth-like planet is likely forming 424 light-years away in a star system called HD 113766, say astronomers using NASA's Spitzer Space Telescope.
XMM-Newton's anniversary view of supernova SN 1987A
Twenty years after the first detection of SN 1987A, the nearest supernova ever detected since the invention of the telescope, XMM-Newton provided a fresh-new view of this object. The source keeps brightening-XMM-Newton confirms.
Hubble finds 16 candidate extrasolar planets far across our Galaxy
The NASA/ESA Hubble Space Telescope has discovered 16 extrasolar planet candidates that are orbiting a variety of distant stars. In accomplishing this, Hubble looked farther into our Milky Way galaxy than has ever successfully been done before in searching for extrasolar planets.
Planet or failed star? One of smallest stellar companions seen by Hubble
Astronomers using the NASA/ESA Hubble Space Telescope have photographed one of the smallest objects ever seen around a normal star beyond our Sun. Weighing in at 12 times the mass of Jupiter, the object is small enough to be a planet.
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Circumstellar Dust Canvas Print - Canvas Art by FineArtAmerica.com This is a beautiful stretched-canvas art print wrapped on 2.5" thick stretcher bars. The print is professionally printed, assembled, and shipped within 2 - 3 business days from our production facility in North Carolina and arrives ready-to-hang on your wall. FineArtAmerica.com is home to more than 20,000 artists from all over the world who entrust us to fulfill their print orders online. We offer a 30-day money-back guarantee on every print that we sell and look forward to helping you select your next piece. |
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Extended Atmospheres and Circumstellar Matter in Spectroscopic Binary Systems (International Astronomical Union Symposia) by A.H. Batten (Editor) | |
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Circumstellar Disks and Envelopes around Young Low-mass Stars: Observing the Cradles of Future Planetary Systems in the Milky Way by Sascha P. Quanz (Author) How do stars - like our sun - form? Where do planets come from? - In the last years astronomers were able to uncover some of the fundamental processes related to these very questions. It showed that circumstellar disks and envelopes of gas, dust and ices are a natural byproduct of the formation process of young stars. These objects grow then more massive by accreting material from the disk, which itself is fed by the envelope in the early phases. In the course of several million years, the envelope is dispersed, infall onto the disk comes to a hold, and most matter is either accreted onto the young star or possibly built into planets.In this book, astronomical observations of young low-mass stars are presented. Using data from modern telescopes the surrounding accretion disks and... |
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The chromosphere of VV cephei and the distribution of circumstellar dust around red giants and supergiants final report, period 1 Aug. 1990 - 31 Jan. 1992 (SuDoc NAS 1.26:193594) by Wendy Hagen Bauer (Author) | |
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Circumstellar Ozma (Primary Contributor) |
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Interrelationships Among Circumstellar, Interstellar, and Interplanetary Dust by Joseph A. Nuth III (Editor), Robert E. Stencel (Editor) | |
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