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Nov.
6, 2009: Once upon a time — roughly four billion
years ago — Mars was warm and wet, much like Earth. Liquid
water flowed on the Martian surface in long rivers that emptied
into shallow seas. A thick atmosphere blanketed the planet
and kept it warm. Living microbes might have even arisen,
some scientists believe, starting Mars down the path toward
becoming a second life-filled planet next door to our own.
But
that's not how things turned out.
Mars
today is bitter cold and bone dry. The rivers and seas are
long gone. Its atmosphere is thin and wispy, and if Martian
microbes still exist, they're probably eking out a meager
existence somewhere beneath the dusty Martian soil.
Above:
Planetary scientists believe that waterfalls may have once
cascaded down these steep cliffs at Echus Chasma on Mars.
Mars has many desiccated landscapes like this one, thought
to have been sculpted by abundant water in the distant past.
Photo credit: Mars Express/ESA. [more]
What
happened? Why did Mars dry up and freeze over? These haunting
questions have long puzzled scientists. A few years from now
we might finally know the answer, thanks to a new orbiter
NASA will send to Mars called MAVEN (short for Mars Atmosphere
and Volatile Evolution).
"The
goal of MAVEN is to figure out what processes were responsible
for those changes in the climate," says Bruce Jakosky,
Principal Investigator for MAVEN at the University of Colorado
at Boulder.
One
way or another, scientists believe, Mars must have lost its
most precious asset: its thick atmosphere of carbon dioxide.
CO2 in Mars's atmosphere is a greenhouse gas, just as it is
in our own atmosphere. A thick blanket of CO2 and other greenhouse
gases would have provided the warmer temperatures and greater
atmospheric pressure required to keep liquid water from freezing
solid or boiling away.
 Over
the last four billion years, Mars somehow lost most of that
blanket. Scientists have proposed various theories for how
that loss happened. Perhaps an asteroid impact blew most of
the atmosphere into space in one catastrophic event. Or maybe
erosion by the solar wind — a stream of charged particles
emanating from the sun — could have slowly stripped the atmosphere
away over eons. The planet's surface might also have absorbed
the CO2 and locked it up in minerals such as carbonate.
Right:
An artist's concept of solar wind blowing away the atmosphere
of Mars. This is just one of several plausible explanations
for what happened to the Red Planet. [video]
Ultimately,
nobody knows for sure where all the missing CO2 went.
MAVEN
will be the first mission to Mars specifically designed to
help scientists understand the ongoing escape of CO2
and other gases into space. The probe will orbit Mars for
at least one Earth-year. At the elliptical orbit's low point,
MAVEN will be 125 km above the surface; its high point will
take it more than 6000 km out into space. This wide range
of altitudes will enable MAVEN to sample Mars's atmosphere
more thoroughly than ever before.
As
it orbits, MAVEN's instruments will track ions and molecules
in this broad cross-section of the Martian atmosphere, thoroughly
documenting the flow of CO2 and other molecules
into space for the first time.
Once
Jakosky and his colleagues know how quickly Mars is losing
CO2 right now, they can extrapolate backward in time to estimate
the total amount lost to space during the last four billion
years. "MAVEN will determine if [loss to space] was the
most important player," Jakosky says.
But
just as important as "how much?" is the question
of "how?"
Conventional
wisdom holds that Mars's atmosphere is vulnerable because
the planet lacks a global magnetic field. Earth's magnetic
field stretches far out into space and envelopes the whole
planet in a protective bubble that deflects the solar wind.
Mars has only regional, patchy magnetic fields that cover
relatively small areas of the planet, mostly in the southern
hemisphere. The rest of the atmosphere is fully exposed to
the solar wind. So the loss could be caused by the slow erosion
of the atmosphere in these exposed areas.
Above:
The loss of martian atmosphere could be caused by a complex
set of mechanisms working simultaneously. MAVEN is equipped
with eight different sensors designed to sort out the confusion.
[more]
David
Brain of UC Berkeley has proposed another, seemingly contrary
possibility. These small magnetic fields might actually hasten
the loss of Mars's atmosphere, Brain suggests.
The
solar wind might buffet those magnetic field lines, occasionally
pinching off a "bubble" of field lines that then
drifts off into space — carrying a large chunk of the atmosphere
with it. If so, having a partial magnetic field might be worse
than having none at all. This possibility was described in
a 2008 Science@NASA story, "Solar
Wind Rips Up Martian Atmosphere."
Some
evidence from NASA's Mars Global Surveyor spacecraft supports
Brain's theory, but decisive measurements will have to wait
for MAVEN, currently scheduled to launch in 2013.
The
mission will be a big step toward understanding what happened
to Mars — how it ended up so cold and dry after such a warm
and watery beginning. After all these years, MAVEN could write
the final chapter in a haunting tale of planetary woe.
Author: Patrick Barry | Editor:
Dr. Tony Phillips | Credit: Science@NASA
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