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Mars
Rovers Sharpen Questions About Livable Conditions
Friday, February 15, 2008
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This
view from NASA's Mars Exploration Rover Opportunity shows
bedrock within a stratigraphic layer informally named
"Lyell," which is the lowermost of three layers
the rover has examined at a bright band around the inside of
Victoria Crater
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Credit:
NASA/JPL-Caltech/Cornell University
Like salt used as a
preservative, high concentrations of dissolved minerals in the
wet, early-Mars environment known from discoveries by NASA's
Opportunity rover may have thwarted any microbes from developing
or surviving.
"Not all water is fit to drink,"
said Andrew Knoll, a member of the rover science team who is a
biologist at Harvard University, Cambridge, Mass.
Opportunity
and its twin, Spirit, began their fifth year on Mars last month,
far surpassing their prime missions of three months. Today, at a
meeting of the American Association for the Advancement of
Science in Boston, scientists and engineers discussed new
observations by the rovers, recent analysis of some earlier
discoveries, and perspectives on which lessons from these rovers'
successes apply to upcoming missions to Mars.
"The
engineering efforts that have enabled the rovers' longevity have
tremendously magnified the science return," said Steve
Squyres of Cornell University, Ithaca, N.Y., principal
investigator for the rovers' science payload. "All of
Spirit's most important findings, such as evidence for hot
springs or steam vents, came after the prime mission."
Opportunity spent recent months examining a bright band
of rocks around the inner wall of a crater. Scientists previously
hypothesized this material might preserve a record of the ground
surface from just before the impact that excavated the crater.
Inspection suggests that, instead, it was at the top of an
underground water table, Squyres reported.
Experiments
with simulated Martian conditions and computer modeling are
helping researchers refine earlier assessments of whether the
long-ago conditions in the Meridiani area studied by Opportunity
would have been hospitable to microbes. Chances look slimmer. "At
first, we focused on acidity, because the environment would have
been very acidic," Knoll said. "Now, we also appreciate
the high salinity of the water when it left behind the minerals
Opportunity found. This tightens the noose on the possibility of
life."
Conditions may have been more hospitable
earlier, with water less briny, but later conditions at Meridiani
and elsewhere on the surface of Mars appear to have been less
hospitable, Knoll said. "Life at the Martian surface would
have been very challenging for the last 4 billion years. The best
hopes for a story of life on Mars are at environments we haven't
studied yet -- older ones, subsurface ones," he said.
NASA's current rovers and orbiters at Mars pursue the
agency's "follow the water" theme for Mars exploration.
They decipher the roles and fate of water on a planet whose most
striking difference from Earth is a scarcity of water. "Our
next missions, Phoenix and Mars Science Laboratory, mark a
transition from water to habitability -- assessing whether sites
where there's been water have had conditions suited to life,"
said Charles Elachi, director of NASA's Jet Propulsion
Laboratory, Pasadena, Calif. "Where conditions were
habitable, later missions may look for evidence of life."
Elachi cited the achievements of Spirit and Opportunity.
"They have worked 16 times longer than planned, driven 20
times farther than planned, and, most important, found diverse
geological records of the effects of water in ancient Martian
environments," he said. "We must not let these
successes lull us into thinking this type of exploration is easy.
Fifty years into the Space Age, we are still in the golden age of
robotic exploration of our solar system, when each mission is
unprecedented in some way as we push the limits of what is
possible. Each mission presents new challenges."
The
Phoenix lander, on course to reach Mars on May 25, will assess
habitability of a shallow subsurface environment of icy soil
farther north than any earlier mission has landed. It revives
technology from missions launched before Spirit and Opportunity.
The following mission, the Mars Science Laboratory rover, will
incorporate many lessons from the current rovers, said that
project's manager, Richard Cook of JPL. "The next rover will
be much bigger to carry the instruments necessary for meeting its
goals, but it would be laughable to consider doing Mars Science
Laboratory without the experience gained from doing the Mars
Exploration Rovers," he said.
The Mars Science
Laboratory rover will weigh about four times as much as Spirit or
Opportunity. "There's no way we could use an airbag
landing," said JPL's Rob Manning, chief engineer for the
future rover. Instead, a rocket-powered hovering stage will lower
it to the surface on a tether. Lessons from Spirit and
Opportunity will come into play when it starts driving, though.
"With the current rovers, we've learned we can trust the
autonomous navigation technology to a level we never expected, so
now we can include that as a capability in our mission design for
Mars Science Laboratory," Manning said.
JPL, a
division of the California Institute of Technology, Pasadena,
built and manages the rovers for NASA's Science Mission
Directorate.
Source:
NASA / JPL
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