Showing posts with label Stardust Mission. Show all posts
Showing posts with label Stardust Mission. Show all posts

03 November 2009

Meteor/Meteorite News- Comet Dust has `Ultra-Primative` Particles 3NOV0

'Ultra-primitive' particles found in comet dust

Washington, D.C.—Dust samples collected by high-flying aircraft in the upper atmosphere have yielded an unexpectedly rich trove of relicts from the ancient cosmos, report scientists from the Carnegie Institution. The stratospheric dust includes minute grains that likely formed inside stars that lived and died long before the birth of our sun, as well as material from molecular clouds in interstellar space. This "ultra-primitive" material likely wafted into the atmosphere after the Earth passed through the trail of an Earth-crossing comet in 2003, giving scientists a rare opportunity to study cometary dust in the laboratory.

At high altitudes, most dust in the atmosphere comes from space, rather than the Earth's surface. Thousands of tons of interplanetary dust particles (IDPs) enter the atmosphere each year. "We've known that many IDPs come from comets, but we've never been able to definitively tie a single IDP to a particular comet," says study coauthor Larry Nittler, of Carnegie's Department of Terrestrial Magnetism. "The only known cometary samples we've studied in the laboratory are those that were returned from comet 81P/Wild 2 by the Stardust mission." The Stardust mission used a NASA-launched spacecraft to collect samples of comet dust, returning to Earth in 2006.

Comets are thought to be repositories of primitive, unaltered matter left over from the formation of the solar system. Material held for eons in cometary ice has largely escaped the heating and chemical processing that has affected other bodies, such as the planets. However, the Wild 2 dust returned by the Stardust mission included more altered material than expected, indicating that not all cometary material is highly primitive.

The IDPs used in the current study were collected by NASA aircraft in April 2003, after the Earth passed through the dust trail of comet Gregg-Skjellerup. The research team, which included Carnegie scientists Nittler, Henner Busemann (now at the University of Manchester, U.K.), Ann Nguyen, George Cody, and seven other colleagues, analyzed a sub-sample of the dust to determine the chemical, isotopic and microstructural composition of its grains. The results are reported on-line in Earth and Planetary Science Letters.*

"What we found is that they are very different from typical IDPs" says Nittler. "They are more primitive, with higher abundances of material whose origin predates the formation of the solar system." The distinctiveness of the particles, plus the timing of their collection after the Earth's passing through the comet trail, point to their source being the Gregg-Skjellerup comet.

"This is exciting because it allows us to compare on a microscopic scale in the laboratory dust particles from different comets," says Nittler. "We can use them as tracers for different processes that occurred in the solar system four-and-a-half billion years ago."

The biggest surprise for the researchers was the abundance of so-called presolar grains in the dust sample. Presolar grains are tiny dust particles that formed in previous generations of stars and in supernova explosions before the formation of the solar system. Afterwards, they were trapped in our solar system as it was forming and are found today in meteorites and in IDPs. Presolar grains are identified by having extremely unusual isotopic compositions compared to anything else in the solar system. But presolar grains are generally extremely rare, with abundances of just a few parts per million in even the most primitive meteorites, and a few hundred parts per million in IDPs. "In the IDPs associated with comet Gregg-Skjellerup they are up to the percent level," says Nittler. "This is tens of times higher abundances than we see in other primitive materials."

Also surprising is the comparison with the samples from Wild 2 collected by the Stardust mission. "Our samples seem to be much more primitive, much less processed, than the samples from Wild 2," says Nittler, "which might indicate that there is a huge diversity in the degree of processing of materials in different comets."

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This work was supported by NASA's Cosmochemistry (NNG004GF61G) and Origins of the Solar System (NNX07AJ71G) programs, the NASA Astrobiology Institute (NAI), the Office of Naval Research and the Office of Basic Energy Sciences of the U.S. Department of Energy under Contract No. DE-AC02-05CH11231. The NASA Astromaterials Acquisition and Curation Office provided the IDPs for the research.

*Busemann, H., et al., Ultra-primitive interplanetary dust particles from the comet 26P/Grigg–Skjellerup dust stream collection, Earth Planet. Sci. Lett. (2009), doi:10.1016/j.epsl.2009.09.007

Authors and affiliations:

Henner Busemann, Department of Terrestrial Magnetism, Carnegie Institution (now at University of Manchester, U.K.)
Ann N. Nguyen, Department of Terrestrial Magnetism, Carnegie Institution
George D. Cody, Geophysical Laboratory, Carnegie Institution
Peter Hoppe, Max Planck Institute for Chemistry, Germany
A.L. David Kilcoyne, Lawrence Berkeley National Laboratory
Rhonda M. Stroud, U.S. Naval Research Laboratory
Thomas J. Zega, U.S. Naval Research Laboratory
Larry R. Nittler, Department of Terrestrial Magnetism, Carnegie Institution

The Carnegie Institution (www.CIW.edu) has been a pioneering force in basic scientific research since 1902. It is a private, nonprofit organization with six research departments throughout the U.S. Carnegie scientists are leaders in plant biology, developmental biology, astronomy, materials science, global ecology, and Earth and planetary science.

The NASA Astrobiology Institute (NAI), founded in 1998, is a partnership between NASA, 16 U.S. teams, and five international consortia. NAI's goal is to promote, conduct, and lead interdisciplinary astrobiology research and to train a new generation of astrobiology researchers. For more information, see http://astrobiology.nasa.gov/nai.

Public release date: 2-Nov-2009

Contact: Larry Nittler
lnittler@ciw.edu
202-478-8460
Carnegie Institution

24 August 2009

Meteor/Meteorite News- Amino Acids from Comets 24AUG09


NASA/JPL

Fetched from a faraway comet, distinctive amino acids

Philadelphia Inquirer
Amino acids have also turned up in meteorites - and reportedly lent a distinctive smell to pieces of the famous Murchison meteorite, which fell on Australia ...

18 August 2009

Latest Meteor/Meteorite News- Life's Building Blocks in Comet 18AUG09

NASA Researchers Make First Discovery of Life's Building Blocks in Comet
http://www.nasa.gov/mission_pages/stardust/news/stardust_amino_acid.html

NASA
August 17, 2009

NASA scientists have discovered glycine, a fundamental building block of
life, in samples of comet Wild 2 returned by NASA's Stardust spacecraft.

"Glycine is an amino acid used by living organisms to make proteins, and
this is the first time an amino acid has been found in a comet," said
Dr. Jamie Elsila of NASA's Goddard Space Flight Center in Greenbelt, Md.
"Our discovery supports the theory that some of life's ingredients
formed in space and were delivered to Earth long ago by meteorite and
comet impacts."

Elsila is the lead author of a paper on this research accepted for
publication in the journal Meteoritics and Planetary Science. The
research will be presented during the meeting of the American Chemical
Society at the Marriott Metro Center in Washington, DC, August 16.

"The discovery of glycine in a comet supports the idea that the
fundamental building blocks of life are prevalent in space, and
strengthens the argument that life in the universe may be common rather
than rare," said Dr. Carl Pilcher, Director of the NASA Astrobiology
Institute which co-funded the research.

Proteins are the workhorse molecules of life, used in everything from
structures like hair to enzymes, the catalysts that speed up or regulate
chemical reactions. Just as the 26 letters of the alphabet are arranged
in limitless combinations to make words, life uses 20 different amino
acids in a huge variety of arrangements to build millions of different
proteins.

Stardust passed through dense gas and dust surrounding the icy nucleus
of Wild 2 (pronounced "Vilt-2") on January 2, 2004. As the spacecraft
flew through this material, a special collection grid filled with
aerogel – a novel sponge-like material that's more than 99 percent empty
space – gently captured samples of the comet's gas and dust. The grid
was stowed in a capsule which detached from the spacecraft and
parachuted to Earth on January 15, 2006. Since then, scientists around
the world have been busy analyzing the samples to learn the secrets of
comet formation and our solar system's history.

"We actually analyzed aluminum foil from the sides of tiny chambers that
hold the aerogel in the collection grid," said Elsila. "As gas molecules
passed through the aerogel, some stuck to the foil. We spent two years
testing and developing our equipment to make it accurate and sensitive
enough to analyze such incredibly tiny samples."

Earlier, preliminary analysis in the Goddard labs detected glycine in
both the foil and a sample of the aerogel. However, since glycine is
used by terrestrial life, at first the team was unable to rule out
contamination from sources on Earth. "It was possible that the glycine
we found originated from handling or manufacture of the Stardust
spacecraft itself," said Elsila. The new research used isotopic analysis
of the foil to rule out that possibility.

Isotopes are versions of an element with different weights or masses;
for example, the most common carbon atom, Carbon 12, has six protons and
six neutrons in its center (nucleus). However, the Carbon 13 isotope is
heavier because it has an extra neutron in its nucleus. A glycine
molecule from space will tend to have more of the heavier Carbon 13
atoms in it than glycine that's from Earth. That is what the team found.
"We discovered that the Stardust-returned glycine has an
extraterrestrial carbon isotope signature, indicating that it originated
on the comet," said Elsila.

The team includes Dr. Daniel Glavin and Dr. Jason Dworkin of NASA
Goddard. "Based on the foil and aerogel results it is highly probable
that the entire comet-exposed side of the Stardust sample collection
grid is coated with glycine that formed in space," adds Glavin.

"The discovery of amino acids in the returned comet sample is very
exciting and profound," said Stardust Principal Investigator Professor
Donald E. Brownlee of the University of Washington, Seattle, Wash. "It
is also a remarkable triumph that highlights the advancing capabilities
of laboratory studies of primitive extraterrestrial materials."

The research was funded by the NASA Stardust Sample Analysis program and
the NASA Astrobiology Institute. NASA's Jet Propulsion Laboratory,
Pasadena, Calif., manages the Stardust mission for NASA's Science
Mission Directorate, Washington. Lockheed Martin Space Systems, Denver,
developed and operated the spacecraft.

To learn more about the mission, visit http://stardustnext.jpl.nasa.gov/


For more about the NASA Goddard astrobiology team, visit
http://astrobiology.gsfc.nasa.gov/analytical