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| water can exist as a liquid near the Martian surface. |
series. Research recently carried out by Nasa’s Curiosity rover, has found that water can exist as a liquid near the Martian surface.
Mars should be probably too cold to sustain liquid water at the surface, but salts in the
soil lower its freezing point – allowing briny films to form.
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| Perchlorates, absorb water vapour from the atmosphere. |
the microbial life forms that we know about.
levels of cosmic radiation – another challenge to life.
Mars, where circumstances are more favorable and promising.
over a Martian year, and from dissimilar instruments carried by the Curiosity rover.
station – measured the relative humidity and temperature at the rover’s landing
site of Gale Crater.
instrument called Dynamic Albedo of Neutrons (DAN). These data were consistent
with water in the soil being bound to perchlorates.
water vapour in the atmosphere.
The results show conditions were right for the brines to form during winter nights at the Martian equator, where Curiosity landed. But the liquid evaporates during the Martian day when temperatures rise.
Javier Martin-Torres, a co-investigator on the Curiosity mission and lead scientist on REMS, told BBC News the detection was indirect but convincing:
“What we see are the conditions for the formation of brines on the surface. It’s similar to when people were discovering the first exoplanets.
“They were not seeing the planets, but they were able to see the gravitational effects on the star.
“These perchlorate salts have a property called deliquescence. They take the water vapour from the atmosphere and absorb it to produce the brines.”
He added: “We see a daily water cycle – which is very important. This cycle is maintained by the brine. On Earth we have an exchange between the atmosphere and the ground through rain. But we don’t have this on Mars.”
While one might think that liquid water would form at warmer temperatures, the formation of brines is the result of an interaction between temperature and atmospheric pressure. It happens that the sweet spot for formation of these liquid films is at colder temperatures.
The fact that the scientists see evidence for these brines at the Martian equator – where conditions are least favourable – means that they might be more persistent at higher latitudes, in areas where the humidity is higher and temperatures are lower.
In these regions they might even be present all year round.
Dark streaks on slopes seen by orbiting spacecraft have long been thought to be the product of running water seeping from the Martian soil. But this interpretation has been contested.
“It’s speculation at this point… but these observations at least support or go in this direction,” said Dr Martin-Torres.
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