WOULD you volunteer to live on a Martian colony if you had to take all your supplies of air and water with you? It鈥檚 unlikely. The only way a colony will survive is by making such life-giving essentials on site. And it looks like it can be done.
Don Sadoway, a natural resources scientist at MIT in Boston, told NASA鈥檚 materials science conference in Huntsville, Alabama, how breathable oxygen can be produced from common iron ores in Martian soil. And chemical engineer Ken Debelak at Vanderbilt University in Tennessee revealed how to extract drinking water from Martian clays and minerals. 鈥淚t鈥檚 the only way you鈥檒l get people to go to a research colony on Mars,鈥 says Sadoway. 鈥淭hey have to know there are resources that let them generate necessities like oxygen and water.鈥
Because the surface of Mars is strewn with chunks of oxide-rich ores, there鈥檚 no need to sink deep mine shafts to reach them. To get at the oxygen, Sadoway has designed a refrigerator-sized electrochemical cell powered by a miniature nuclear reactor. It passes a 450-amp current through the ores, melting and electrolysing them. At the negative electrode, a mixture of metals separates out, while oxygen gas is released at the positive electrode.
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People need around 2.75 kilograms of oxygen a day, which his cell will scavenge from 8 kilograms of ore. The only by-product would be impure iron. Sadoway鈥檚 cell wouldn鈥檛 solve all the colonists鈥 problems, though. The oxygen would still need to be mixed with nitrogen at the very least to make it more akin to breathable air.
And what about water? Despite NASA鈥檚 recent fanfare about finding water ice on Mars, getting at it is another matter. The frozen poles may well contain large amounts of ice, but these inhospitable regions would scarcely be ideal places to set up a research outpost. And even if there is water ice hidden in more agreeable climes, it probably isn鈥檛 drinkable as it will more than likely be very salty (快猫短视频, 8 June, p 11).
A better plan would be to extract water that is chemically bound up in clays and minerals in the Martian soil, says Debelak. His idea is to use the Martian atmosphere, which is 95 per cent CO2, to do the job. When CO2 is heated above 31 掳C and compressed to more than 72 times atmospheric pressure, it becomes 鈥渟upercritical鈥. In this state, it acts as a very effective solvent, and is often used to decaffeinate coffee.
Debelak found that supercritical CO2 can remove 8 per cent of the water in hydrated minerals. It鈥檚 not much, but it鈥檚 simple and effective. Dropping the pressure of the CO2 to 60 atmospheres allows the water to condense out. 鈥淭he water鈥檚 pretty clean, it just has a bit of CO2 in it,鈥 he adds. 鈥淭he things we鈥檙e talking about here are for when people are seriously thinking about research outposts on Mars,鈥 says Debelak. 鈥淲hether or not Congress has got the stomach for something like this further down the road is difficult to say.鈥