A self portrait of rover Curiosity |
Curiosity's formidable arsenal of scientific instruments has detected traces of water chemically bound to the Martian dust that seems to be covering the entire planet. The finding, among several in the five studies published online Thursday by the journal Science, may explain mysterious water signals picked up by satellites in orbit around the Red Planet.
The soil that covers Mars' surface in Gale Crater, where Curiosity landed last year, seems to have two major components, according to data from the rover's laser-shooting Chemistry and Camera instrument. One is a coarse soil with millimeter-wide grains that probably came from the rocks around them; the other is very fine, with grains often a few micrometers in size, the ChemCam data show.
The fine-grained soil doesn't really match the rocks around it, said Pierre-Yves Meslin of the University of Toulouse in France, who led one of the studies. But it does seem to match the stuff found at sites where other rovers and landers touched down. That means it's probably distributed over much or all of the planet, kicked up and carried far in the fierce dust storms that can shroud the planet in a reddish haze.
The researchers say they don't know where that soil comes from, whether it's created in many places or has one source that gets picked up and blown all over.
Either way, it's a handy, naturally averaged sample of the Martian surface, said Indiana University mineralogist David Bish, who led a different study.
Perhaps the most intriguing thing about this fine soil is that ChemCam's readings detected a hydrogen signal, which could explain why satellites orbiting Mars have picked up a mysterious water signal in the past, Meslin said.
"It's actually kind of exciting because it's water yet again on Mars, but it's in a different material than we had recognized," said Caltech geologist John Grotzinger, the mission's project scientist. "So what Curiosity is doing is just demonstrating that water is present in a number of ways. It just adds to the diversity."
But another study based on data from Curiosity's Chemistry and Mineralogy tool — part of the dirt-digesting lab in the rover's belly — found no sign of water in soil samples taken from Rocknest, a sandy dune of a pit stop on the rover's way to a region dubbed Yellowknife Bay. That's because CheMin uses X-ray diffraction to bounce high-energy light off of a mineral's crystalline structure. If the soil isn't in crystalline form, there's no way for CheMin to see it.
All this means the hydrogen signal seen by ChemCam must have been coming from the amorphous, or non-crystalline, portion, which makes up a significant minority of the soil, said Bish, who led the CheMin study.
Sure enough, Curiosity's Sample Analysis at Mars instrument cooked up a tiny sample in its little oven and found that roughly 1.5 percent to 3 percent of the soil was made of water. The scientists think this water may have come from the atmosphere, pulled out of the thin air.
Bish said it was interesting that CheMin found no signs of minerals that formed in water, since looking for such clays was "one of the reasons for going to Gale Crater." Inside Gale Crater lies a 3-mile-high mountain called Mt. Sharp, whose layers could be rich in clays that hold answers to whether Mars was hospitable to life.
A view of Gale crater near the Mars Equator |
Another of the studies focused on the rock known as Jake M, named after NASA engineer Jake Matijevic, who died shortly after the rover landed in 2012. The researchers didn't intend to study the rock — they analyzed it with Curiosity's alpha-particle X-ray spectrometer in order to help put ChemCam's measurements in context, said Caltech geologist Edward Stolper, lead author of that study.
Jake M is unlike any volcanic rock seen on Mars. It's rich in alkaline magma, which told the researchers that it had been created under high pressure — and perhaps in the presence of water, Stolper said. In fact, it looks something like a relatively uncommon rock on Earth called a mugearite, found on ocean islands and in rift zones.
The rock's composition also told scientists that it was clearly made of the leftovers after other minerals had crystallized out. That led them to believe that the heating and cooling and movement of magma that used to occur beneath Mars' mantle were a lot more complicated than they had thought.
"We see evidence for a more evolved planet," Grotzinger said, "so it looks like it was headed in more of a direction like Earth."
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