Dwayne Brown
Headquarters, Washington
202-358-1726
dwayne.c.brown@nasa.gov
Guy Webster, D.C. Agle
Jet Propulsion Laboratory, Pasadena,
Calif.
818-354-6278, 818-393-9011
guy.webster@jpl.nasa.gov /
agle@jpl.nasa.gov
WASHINGTON -- NASA's most advanced
planetary rover is on a precise course for an early August landing beside a
Martian mountain to begin two years of unprecedented scientific detective work.
However, getting the Curiosity rover to the surface of Mars will not be easy.
"The Curiosity landing is the
hardest NASA mission ever attempted in the history of robotic planetary
exploration," said John Grunsfeld, associate administrator for NASA's
Science Mission Directorate, at NASA Headquarters in Washington. "While
the challenge is great, the team's skill and determination give me high
confidence in a successful landing."
The Mars Science Laboratory (MSL)
mission is a precursor mission for future human mission to Mars. President
Obama has set a challenge to reach the Red Planet in the 2030s.
To achieve the precision needed for
landing safely inside Gale Crater, the spacecraft will fly like a wing in the
upper atmosphere instead of dropping like a rock. To land the 1-ton rover, an
air-bag method used on previous Mars rovers will not work. Mission engineers at
NASA's Jet Propulsion Laboratory (JPL) in Pasadena, Calif., designed a
"sky crane" method for the final several seconds of the flight. A
backpack with retro-rockets controlling descent speed will lower the rover on
three nylon cords just before touchdown.
During a critical period lasting only
about seven minutes, the MSL spacecraft carrying Curiosity must decelerate from
about 13,200 mph (about 5,900 meters per second) to allow the rover to land on
the surface at about 1.7 mph (three-fourths of a meter per second). Curiosity
is scheduled to land at approximately 1:31 a.m. EDT Aug. 6 (10:31 p.m. PDT Aug.
5).
"Those seven minutes are the most
challenging part of this entire mission," said Pete Theisinger, JPL's MSL
project manager. "For the landing to succeed, hundreds of events will need
to go right, many with split-second timing and all controlled autonomously by
the spacecraft. We've done all we can think of to succeed. We expect to get
Curiosity safely onto the ground, but there is no guarantee. The risks are
real."
During the initial weeks after the
actual landing, JPL mission controllers will put the rover through a series of
checkouts and activities to characterize its performance on Mars while
gradually ramping up scientific investigations. Curiosity then will begin
investigating whether an area with a wet history inside Mars' Gale Crater ever
has offered an environment favorable for microbial life.
"Earlier missions have found that
ancient Mars had wet environments," said Michael Meyer, lead scientist for
NASA's Mars Program at NASA Headquarters. "Curiosity takes us the next
logical step in understanding the potential for life on Mars."
Curiosity will use tools on a robotic
arm to deliver samples from Martian rocks and soils into laboratory instruments
inside the rover that can reveal chemical and mineral composition. A laser
instrument will use its beam to induce a spark on a target and read the spark's
spectrum of light to identify chemical elements in the target.
Other instruments on the car-sized rover
will examine the surrounding environment from a distance or by direct touch
with the arm. The rover will check for the basic chemical ingredients for life
and for evidence about energy available for life. It also will assess factors
that could be hazardous for life, such as the radiation environment.
"For its ambitious goals, this
mission needs a great landing site and a big payload," said Doug
McCuistion, director of the Mars Exploration Program at NASA Headquarters.
"During the descent through the atmosphere, the mission will rely on bold
techniques enabling use of a smaller target area and a heavier robot on the
ground than were possible for any previous Mars mission. Those techniques also
advance us toward human-crew Mars missions, which will need even more precise
targeting and heavier landers."
The chosen landing site is beside a
mountain informally called Mount Sharp. The mission's prime destination lies on
the slope of the mountain. Driving there from the landing site may take many
months.
"Be patient about the drive. It
will be well worth the wait and we are apt to find some targets of interest on
the way," said John Grotzinger, MSL project scientist at the California
Institute of Technology in Pasadena. "When we get to the lower layers in
Mount Sharp, we'll read them like chapters in a book about changing
environmental conditions when Mars was wetter than it is today."
In collaboration with Microsoft Corp., a
new outreach game was unveiled Monday to give the public a sense of the
challenge and adventure of landing in a precise location on the surface. Called
"Mars Rover Landing," the game is an immersive experience for the
Xbox 360 home entertainment console that allows users to take control of their
own spacecraft and face the extreme challenges of landing a rover on Mars.
"Technology is making it possible
for the public to participate in exploration as it never has before," said
Michelle Viotti, JPL's Mars public engagement manager. "Because Mars
exploration is fundamentally a shared human endeavor, we want everyone around
the globe to have the most immersive experience possible."
NASA has several other forthcoming
experiences geared for inspiration and learning in science, technology,
engineering and mathematics. Information about many ways to watch and
participate in the Curiosity's landing and the mission on the surface of Mars
is available at http://mars.jpl.nasa.gov/msl/participate.
MSL is a project of NASA's Science
Mission Directorate. The mission is managed by JPL. Curiosity was designed,
developed and assembled at JPL.
Follow the mission on Facebook and on
Twitter at http://www.facebook.com/marscuriosity , and http://www.twitter.com/marscuriosity.
For information about the mission and to
use the new video game and other education-related tools, visit http://www.nasa.gov/mars
and http://mars.jpl.nasa.gov/msl/.
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