Dec. 20, 2012

Karen Jenvey
Ames Research Center, Moffett Field, Calif. 
650-604-4789 
karen.jenvey@nasa.gov
RELEASE: 12-93AR

NASA RESEARCHERS STRIKE SCIENTIFIC GOLD WITH METEORITE

Click image for full resolution.
Fragments of the Sutter’s Mill meteorite fall collected by NASA Ames 
and SETI Institute meteor astronomer Dr. Peter Jenniskens in the 
evening of Tuesday April 24, two days after the fall. This was the 
second recovered find. 
Image credit: NASA / Eric James <h3>Images from the search</h3>  Click 
image for full resolution.
Dr. Peter Jenniskens take a closer look at the image from the AVS 
Cineflex HiDEF camera mounted on the nose of the Eureka Airship. Mike 
Coop, can be seen in the background checking the map, further back 
other flight members continue to look for potential impact sites. 
Image credit: NASA / Eric James

Click image for full resolution.
NASA Ames and SETI Institute meteor astronomer Dr. Peter Jenniskens 
collects the Sutter’s Mill meteorites using aluminum foil to not 
contaminate the stones by touch. April 24, 2012 
Image credit: NASA / Courtesy of Dr. Peter Jenniskens

Click image for full resolution.
Merv de Haas horse pasture, near Lotus, California, which is the site 
of where the Sutter’s Mill meteorite fragment was found on May 3, 
2012. The site was searched during ground search using aerial 
sightings. 
Image credit: NASA / Ed Schilling

Click here for a story about the search.  MOFFETT FIELD, Calif. - 
Scientists found treasure when they studied a meteorite that was 
recovered April 22, 2012 at Sutter's Mill, the gold discovery site 
that led to the 1849 California Gold Rush. Detection of the falling 
meteorites by Doppler weather radar allowed for rapid recovery so 
that scientists could study for the first time a primitive meteorite 
with little exposure to the elements, providing the most pristine 
look yet at the surface of primitive asteroids. 

An international team of 70 researchers reported in today's issue of 
“Science” that this meteorite was classified as a Carbonaceous-Mighei 
or CM-type carbonaceous chondrite and that they were able to identify 
for the first time the source region of these meteorites.

"The small three meter-sized asteroid that impacted over California’s 
Sierra Nevada came in at twice the speed of typical meteorite falls," 
said lead author and meteor astronomer Peter Jenniskens of the SETI 
Institute, Mountain View, Calif., and NASA Ames Research Center, 
Moffett Field, Calif. "Clocked at 64,000 miles per hour, it was the 
biggest impact over land since the impact of the four meter-sized 
asteroid 2008 TC3, four years ago over Sudan."

The asteroid approached on an orbit that still points to the source 
region of CM chondrites. From photographs and video of the fireball, 
Jenniskens calculated that the asteroid approached on an unusual 
low-inclined almost comet-like orbit that reached the orbit of 
Mercury, passing closer to the sun than known from other recorded 
meteorite falls. 

"It circled the sun three times during a single orbit of Jupiter, in 
resonance with that planet," Jenniskens said. Based on the unusually 
short time that the asteroid was exposed to cosmic rays, there was 
not much time to go slower or faster around the sun. That puts the 
original source asteroid very close to this resonance, in a low 
inclined orbit. 

"A good candidate source region for CM chondrites now is the Eulalia 
asteroid family, recently proposed as a source of primitive C-class 
asteroids in orbits that pass Earth," adds Jenniskens.

After the asteroid broke up in the atmosphere, weather radar briefly 
detected a hailstorm of falling meteorites over the townships of 
Coloma and Lotus in California. This enabled a rapid recovery that 
permitted the most pristine look yet at a CM-type carbonaceous 
chondrite.

"This was the first time a rare carbonaceous chondrite meteorite was 
recovered based on such weather radar detection," said Marc Fries of 
the Planetary Science Institute in Tucson, Arizona, who pioneered the 
use of this technique. "Meteorites were found mostly under the radar 
footprint."

Of the estimated 100,000-pound asteroid, less than two pounds was 
recovered on the ground in the form of 77 meteorites. The biggest was 
205 grams. Some of the key meteorites discussed in this work were 
found by volunteer search teams led by Jenniskens. 

"The entire Ames community really came together in the search for 
these meteorites. People work at NASA because they love science and 
that was very evident when we saw the overwhelming response of 
volunteers from Ames wanting to be a part of this,” said Pete Worden, 
director of NASA Ames Research Center. 

"The meteorite was a jumbled mess of rocks, called a regolith breccia, 
that originated from near the surface of a primitive asteroid," said 
meteoriticist Derek Sears of NASA Ames.

NASA and the Japanese space agency (JAXA) have plans to target 
asteroids similar to the one recovered at Sutter’s Mill. The Sutter's 
Mill meteorite provides a rare glimpse of what these space missions 
may find. 

"NASA's robotic OSIRIS-REx mission is currently being prepared to 
bring back a pristine sample of an asteroid named 1999 RQ36," said 
co-author and mission co-investigator Scott Sandford of NASA Ames. 
"In addition, Sutter's Mill has the same reflective properties as 
near-Earth asteroid, 1999 JU3, the mission target of the Hayabusa 2 
sample return mission currently being prepared by the Japanese space 
agency, JAXA."

The rapid recovery resulted in the detection of compounds that quickly 
disappear once a meteorite lands on Earth. Mike Zolensky, a 
mineralogist at NASA’s Johnson Space Flight Center, Houston, was 
surprised to detect the mineral oldhamite, a calcium sulfide, known 
in the past to disappear from contact with water by simply breathing 
on it. 

"This mineral was known before mainly from rare enstatite chondrites," 
said Zolensky, "and its presence in the regolith breccia could mean 
that primitive and highly evolved asteroids collided with each other 
even at early times when the debris accumulated that now makes the 
meteorite matrix."

A wide array of carbon-containing compounds was detected that quickly 
reacted with water once in the Earth's environment. It is thought 
that the carbon atoms in our body may have been brought to Earth by 
such primitive asteroids in the early stages of our planet’s history. 


"Amino acids were few in this meteorite because this particular 
meteorite appears to have been slightly heated in space before it 
arrived at Earth," said Danny Glavin of NASA’s Goddard Space Flight 
Center, Greenbelt, Md. 

It appears that different parts of the meteorite had a different 
thermal alteration history. Heating also removed some of the water 
that used to move salts around in the asteroid. 

"Samples collected before it rained on the meteorite fall area still 
contained such salts," said George Cooper of NASA Ames, "but Sutter's 
Mill was less altered by water in the asteroid itself than other CM 
type meteorites."

"Only 150 parts per billion of Sutter's Mill was actual gold," said 
co-author and cosmochemist Qing-zhu Yin of U.C. Davis, Davis, Calif., 
"but all of it was scientific gold. With 78 other elements measured, 
Sutter's Mill provides one of the most complete records of elemental 
compositions documented for such primitive meteorites."

To view a video about the search for this meteorite, visit:

http://www.nasa.gov/multimedia/videogallery/index.html?media_id=143134601 

	
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