NASA to Host Dec.13 Teleconference on Twin Probes Mission Ending Moon Impact
PASADENA,
Calif. -- NASA will host a media teleconference at 10:30 a.m. PST (1:30
p.m. EST) Thursday, Dec. 13, to provide an overview of events leading
up to twin spacecraft being commanded to impact the moon's surface on
Dec. 17 at approximately 2:28 p.m.
NASA's Gravity Recovery and Interior Laboratory (GRAIL) mission, whose two washing machine-sized probes were named Ebb and Flow by elementary school students in Bozeman, Montana, via a nationwide contest, have successfully completed their prime missions and have only days to go on their extended mission science collection. As planned, the duo is running low on fuel. They have been orbiting the moon since New Year's Eve and New Year's Day, respectively, giving scientists unprecedented detail about the moon's internal structure and composition.
For teleconference dial-in information, reporters must send their name, media affiliation and telephone number to Elena Mejia at elena.mejia@jpl.nasa.gov or call NASA's Jet Propulsion Laboratory Media Relations Office at 818-354-5011.
Audio and visuals of the event will be streamed live online at:
NASA's Gravity Recovery and Interior Laboratory (GRAIL) mission, whose two washing machine-sized probes were named Ebb and Flow by elementary school students in Bozeman, Montana, via a nationwide contest, have successfully completed their prime missions and have only days to go on their extended mission science collection. As planned, the duo is running low on fuel. They have been orbiting the moon since New Year's Eve and New Year's Day, respectively, giving scientists unprecedented detail about the moon's internal structure and composition.
For teleconference dial-in information, reporters must send their name, media affiliation and telephone number to Elena Mejia at elena.mejia@jpl.nasa.gov or call NASA's Jet Propulsion Laboratory Media Relations Office at 818-354-5011.
Audio and visuals of the event will be streamed live online at:
and
For more information about the mission, visit:
This movie shows the variations in the
lunar gravity field as measured by NASA's Gravity Recovery and Interior
Laboratory (GRAIL) during the primary mapping mission from March to May
2012. Very precise microwave measurements between two spacecraft, named
Ebb and Flow, were used to map gravity with high precision and high
spatial resolution.
› Download video › Image gallery
Closer Look at Lunar Highland Crust
This image depicting the porosity of the lunar highland crust was derived using bulk density data from NASA's GRAIL mission and independent grain density measurements from NASA's Apollo moon mission samples as well as orbital remote-sensing data. Red corresponds to higher than average porosities and blue corresponds to lower than average porosities. White denotes regions that contain mare basalts (thin lines) and that were not analyzed.The 12 percent average porosity of the highland crust is a consequence of fractures generated by billions of years of impact cratering. The crustal porosities in the interiors of many impact basins are lower than their surroundings, a result of high temperatures experienced at the time of crater formation. In contrast, the porosities immediately exterior to many impact basins are higher than average as a result of fracturing by impact-generated shock waves and the deposition of impact ejecta.
Image Credit: NASA/JPL-Caltech/ IPGP
Download Image
› Full SizeGRAIL's Gravity Field of the Moon
This map shows the gravity field of the moon as measured by NASA's GRAIL mission. The viewing perspective, known as a Mercator projection, shows the far side of the moon in the center and the nearside (as viewed from Earth) at either side.Units are milliGalileos where 1 Galileo is 1 centimeter per second squared. Reds correspond to mass excesses which create areas of higher local gravity, and blues correspond to mass deficits which create areas of lower local gravity.
Image credit: NASA/ARC/MIT
PASADENA, Calif. -- Twin NASA probes orbiting Earth's moon have
generated the highest resolution gravity field map of any celestial
body.
The new map, created by the Gravity Recovery and Interior Laboratory
(GRAIL) mission, is allowing scientists to learn about the moon's
internal structure and composition in unprecedented detail. Data from
the two washing machine-sized spacecraft also will provide a better
understanding of how Earth and other rocky planets in the solar system
formed and evolved.
The gravity field map reveals an abundance of features never before seen
in detail, such as tectonic structures, volcanic landforms, basin
rings, crater central peaks and numerous simple, bowl-shaped craters.
Data also show the moon's gravity field is unlike that of any
terrestrial planet in our solar system.
These are the first scientific results from the prime phase of the
mission, and they are published in three papers in the journal Science.
"What this map tells us is that more than any other celestial body we
know of, the moon wears its gravity field on its sleeve," said GRAIL
Principal Investigator Maria Zuber of the Massachusetts Institute of
Technology in Cambridge. "When we see a notable change in the gravity
field, we can sync up this change with surface topography features such
as craters, rilles or mountains."
According to Zuber, the moon's gravity field preserves the record of
impact bombardment that characterized all terrestrial planetary bodies
and reveals evidence for fracturing of the interior extending to the
deep crust and possibly the mantle. This impact record is preserved, and
now precisely measured, on the moon.
The probes revealed the bulk density of the moon's highland crust is
substantially lower than generally assumed. This low-bulk crustal
density agrees well with data obtained during the final Apollo lunar
missions in the early 1970s, indicating that local samples returned by
astronauts are indicative of global processes.
"With our new crustal bulk density determination, we find that the
average thickness of the moon's crust is between 21 and 27 miles (34 and
43 kilometers), which is about 6 to 12 miles (10 to 20 kilometers)
thinner than previously thought," said Mark Wieczorek, GRAIL
co-investigator at the Institut de Physique du Globe de Paris. "With
this crustal thickness, the bulk composition of the moon is similar to
that of Earth. This supports models where the moon is derived from Earth
materials that were ejected during a giant impact event early in solar
system history."
The map was created by the spacecraft transmitting radio signals to
define precisely the distance between them as they orbit the moon in
formation. As they fly over areas of greater and lesser gravity caused
by visible features, such as mountains and craters, and masses hidden
beneath the lunar surface, the distance between the two spacecraft will
change slightly.
"We used gradients of the gravity field in order to highlight smaller
and narrower structures than could be seen in previous datasets," said
Jeff Andrews-Hanna, a GRAIL guest scientist with the Colorado School of
Mines in Golden. "This data revealed a population of long, linear
gravity anomalies, with lengths of hundreds of kilometers, crisscrossing
the surface. These linear gravity anomalies indicate the presence of
dikes, or long, thin, vertical bodies of solidified magma in the
subsurface. The dikes are among the oldest features on the moon, and
understanding them will tell us about its early history."
While results from the primary science mission are just beginning to be
released, the collection of gravity science by the lunar twins
continues. GRAIL's extended mission science phase began Aug. 30 and will
conclude Dec. 17. As the end of mission nears, the spacecraft will
operate at lower orbital altitudes above the moon.
When launched in September 2011, the probes were named GRAIL A and B.
They were renamed Ebb and Flow in January by elementary students in
Bozeman, Mont., in a nationwide contest. Ebb and Flow were placed in a
near-polar, near-circular orbit at an altitude of approximately 34 miles
(55 kilometers) on Dec. 31, 2011, and Jan. 1, 2012, respectively.
NASA's Jet Propulsion Laboratory in Pasadena, Calif., manages the
mission for NASA's Science Mission Directorate in Washington. GRAIL is
part of the Discovery Program managed at NASA's Marshall Space Flight
Center in Huntsville, Ala. Lockheed Martin Space Systems of Denver built
the spacecraft.
To view the lunar gravity map,
visit http://bit.ly/grailtour .
For more information about the mission,
visit: http://www.nasa.gov/grail .
JPL is a division of the California Institute of Technology in Pasadena.
DC Agle 818-393-9011
Jet Propulsion Laboratory, Pasadena, Calif.
agle@jpl.nasa.gov
Dwayne Brown 202-358-1726
NASA Headquarters, Washington
Dwayne.c.brown@nasa.gov
Sarah McDonnell 617-253-8923
Massachusetts Institute of Technology, Cambridge
s_mcd@mit.edu
NASA
Jet Propulsion Laboratory, Pasadena, Calif.
agle@jpl.nasa.gov
Dwayne Brown 202-358-1726
NASA Headquarters, Washington
Dwayne.c.brown@nasa.gov
Sarah McDonnell 617-253-8923
Massachusetts Institute of Technology, Cambridge
s_mcd@mit.edu
NASA
Guillermo Gonzalo Sánchez Achutegui
ayabaca@gmail.com
ayabaca@hotmail.com
ayabaca@yahoo.com
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