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NASA Space Science News
What
makes the Red Planet red?
Scientists
think Mars has a bad case of rust. Martian soil is full
of iron-bearing compounds that, over the eons, have reacted
with trace amounts of oxygen and water vapor in Mars' atmosphere
to form iron oxide -- the same chemical that covers innumerable
rusty nails in garages and workshops on Earth.
Above:
A panoramic view of Mars
from the Sagan Memorial Station where Pathfinder landed
in 1997.
The
word "rust" conjures up images of things that
are red --like Mars and old nails-- but not all iron oxide
is the same color. Here on Earth a gray-hued variety of
iron oxide, a mineral called hematite, can precipitate in
hot springs or in standing pools of water.
Gray
hematite is not the sort of rust you might expect to find
on a desert-dry planet like Mars. But perhaps Mars wasn't
always as dry as it is today. There are many signs of ancient
or hidden water on the Red Planet including flash-flood
gullies, sedimentary layers ... and hematite.
In 1998,
an infrared spectrometer on NASA's Mars Global Surveyor
(MGS) spacecraft detected a substantial deposit of gray
hematite near the Martian equator, in a 500 km-wide region
called Sinus Meridiani. The discovery raised the tantalizing
possibility that hot springs were once active on Mars.
Right:
An artist's concept of ancient
hot springs on Mars where gray hematite might have collected.
"We
believe that the gray hematite is very strong evidence that
water was once present in that area," said Victoria
Hamilton, a planetary geologist at Arizona State University
(ASU). "We think the deposit is fairly old. It was
buried, perhaps, for several hundred million years or more
and now it's being exposed by wind erosion."
Gray
hematite has the same chemical formula (Fe2O3) as its rusty-red
cousin, but a different crystalline structure. Red rust
is fine and powdery; typical grains are hundreds of nanometers
to a few microns across. Gray hematite crystals are larger,
like grains of sand.
"Red
and gray iron oxides on Mars are really just different forms
of the same mineral," explained Hamilton. "If
you ground up the gray hematite into a fine powder it would
turn red because the smaller grains scatter red light."
The
coarse-grained structure of gray hematite is important,
says ASU's Jack Farmer, head of the NASA Astrobiology Institute's
Mars Focus Group, because "to get that kind of coarsening
of the crystallinity, you would need to have a reasonable
amount of water available" where the hematite formed.
The
link between water and gray hematite makes the so-called
"Hematite Site" (Sinus Meridiani) an alluring
target for future Mars landers as well as for remote sensing
instruments on the 2001 Mars Odyssey spacecraft -- slated
to launch on April 7th.
Left:
The distribution of hematite
in Sinus Meridiani. This image, courtesy of Phil Christensen,
is reprinted from "Global mapping of Martian hematite
mineral deposits: Remnants of water-driven processes on
early Mars", by P.R. Christensen et al., Journal of
Geophysical Research, in press.
Odyssey
will carry an infrared imaging camera called THEMIS (short
for Thermal Emission Imaging System) that can identify surface
minerals from orbit by analyzing their spectral "fingerprints."
"It
turns out that all materials vibrate at the atomic scale,"
explains Hamilton. "For minerals, the rate at which
the atoms vibrate corresponds to the thermal infrared part
of the electromagnetic spectrum, between about 5 and 50
microns. Those are longer wavelengths than what our eyes
can see." Every mineral has a unique infrared spectrum
that identifies it as surely as the fingerprints of a human
being, she added.
THEMIS
is a "next-generation" instrument that can capture
sharper images than TES, the Thermal Emission Spectrometer
that is orbiting Mars now aboard Mars Global Surveyor. THEMIS
will be able to discern the mineral content of geological
features only 100 meters across, compared to 3 km for TES.
Above:
The spectral "fingerprint"
of hematite. The peaks and valleys of this graph are characteristic
of infrared emissions from hematite. Courtesy of the Arizona
State University Thermal Emission Spectral Library.
Of many
candidate landing sites for NASA's 2003 Mars Exploration
Rovers, the Sinus Meridiani region is one of the most intriguing
to scientists. THEMIS data could help planners pinpoint
the best places to land, especially if the maps reveal deposits
of other aqueous minerals such as carbonates or sulfates.
"The
interesting thing about carbonates and sulfates," says
Phil Christensen, principal investigator for THEMIS, "is
that these materials can be better (than hematite) at preserving
a fossil record. Some of them, like carbonates, would also
indicate that standing bodies of water were present on the
surface." Hematite minerals, on the other hand, might
have been formed by hydrothermal water deep underground.
So far,
instruments on MGS have found no direct evidence for carbonates
or sulfates anywhere on Mars. The absence of such aqueous
minerals is a mystery if liquid Martian water -- in the
form of lakes, rivers or oceans -- was indeed abundant in
the planet's geological past.
Christensen
cautions that the spatial resolution of TES on Mars Global
Surveyor might not have been good enough to detect small
deposits of carbonates. With its superior resolution, THEMIS
has a better chance. For example, TES would not have detected
the carbonate layers in Earth's Grand Canyon, but THEMIS
would.
Above:
THEMIS's infrared capabilities
will significantly improve the data from TES, a similar
instrument on Mars Global Surveyor. THEMIS map pixels will
occupy just 0.01 square-kilometers compared to 9 square-km
per pixel for TES. This image shows how California's Saline
Valley might appear to both instruments.
Until
someone finds signs of carbonates or sulfates on Mars, perhaps
in some future THEMIS image, gray hematite remains the best
known mineral signpost for ancient Martian water.
The
hematite makes scientists wonder, was there once a Martian
equivalent of Yellowstone National Park where steaming hot
springs formed hematite-laden pools? And are underground
springs still present there today? Human exploration of
the Red Planet could hinge on the answers. And there may
be no better place to find out than Sinus Meridiani, where
the lure of hematite is powerful indeed.
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