by ANDY FLEMING
Fossilized hydrology: A 3-D image of an impact crater in the
Nilosyrtis area on the Martian surface shows long pipe-like ridges, fossilized
evidence of ancient subsurface water flow. Credit: NASA Mars Reconnaissance
Orbiter.
Networks of narrow
ridges found in impact craters on Mars appear to be the fossilized remnants of
underground cracks through which water once flowed, according to a new analysis
by researchers from Brown University.
The study bolsters the idea that the
subsurface environment on Mars once had an active hydrology and could be a good
place to search for evidence of past life. The research was conducted by Lee
Saper, a recent Brown graduate, with Jack Mustard, professor of geological
sciences.
The ridges, many of
them hundreds of meters in length and a few meters wide, had been noted in
previous research, but how they had formed was not known. Saper and Mustard
thought they might once have been faults and fractures that formed underground
when impact events rattled the planet's crust. Water, if present in the
subsurface, would have circulated through the cracks, slowly filling them in
with mineral deposits, which would have been harder than the surrounding rocks.
As those surrounding rocks eroded away over millions of years, the seams of
mineral-hardened material would remain in place, forming the ridges seen today.
To test their
hypothesis, Saper and Mustard mapped over 4,000 ridges in two crater-pocked
regions on Mars, Nili Fossae and Nilosyrtis. Using high-resolution images from
NASA's Mars Reconnaissance Orbiter, the researchers noted the orientations of
the ridges and composition of the surrounding rocks.
The orientation data
is consistent with the idea that the ridges started out as fractures formed by
impact events. A competing hypothesis suggests that these structures may have
been sheets of volcanic magma intruding into the surrounding rock, but that
doesn't appear to be the case. At Nili Fossae, the orientations are similar to
the alignments of large faults related to a mega-scale impact. At Nilosyrtis,
where the impact events were smaller in scale, the ridge orientations are
associated with each of the small craters in which they were found. "This
suggests that fracture formation resulted from the energy of localized impact
events and are not associated with regional-scale volcanism," Saper said.
Importantly, Saper
and Mustard also found that the ridges exist exclusively in areas where the
surrounding rock is rich in iron-magnesium clay, a mineral considered to be a tell-tale
sign that water had once been present in the rocks.
"The association
with these hydrated materials suggests there was a water source
available," Saper said. "That water would have flowed along the path
of least resistance, which in this case would have been these fracture
conduits."
As that water flowed,
dissolved minerals would have been slowly deposited in the conduits, in much
the same way mineral deposits can build up and eventually clog drain pipes.
That mineralized material would have been more resistant to erosion than the
surrounding rock. And indeed, Saper and Mustard found that these ridges were
only found in areas that were heavily eroded, consistent with the notion that
these are ancient structures revealed as the weaker surrounding rocks were
slowly peeled away by wind.
Taken together, the
results suggest the ancient Martian subsurface had flowing water and may have
been a habitable environment.
"This gives us a
point of observation to say there was enough fracturing and fluid flow in the
crust to sustain at least a regionally viable subsurface hydrology," Saper
said. "The overarching theme of NASA's planetary exploration has been to
follow the water. So if in fact these fractures that turned into these ridges
were flowing with hydrothermal fluid, they could have been a viable
biosphere."
Saper hopes that the
Curiosity rover, currently making its way across its Gale Crater landing site,
might be able to shed more light on these types of structures.
"In the site at
Gale Crater, there are thought to be mineralized fractures that the rover will
go up and touch," Saper said. "These are very small and may not be
exactly the same kind of feature we studied, but we'll have the opportunity to
crush them up and do chemical analysis on them. That could either bolster our
hypothesis or tell us we need to explore other possibilities."
Original Source:
Brown University
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