How brine can help create breathable air and fuel on Mars
Oxygen from martian brine
A new way has emerged, however, that would consume 25 times less electrical power to produce the same amount of oxygen. No matter whether you use solar cells or a radioactive source to generate your electricity, the available power is limited, so this is an important gain.
In the new study, a team from Washington University in the US, demonstrate how electrolysis can be used efficiently to produce oxygen and hydrogen simultaneously from brine. It turns out that when you start from a concentrated solution of magnesium perchlorate, it is relatively easy to split the water component of the brine into oxygen and hydrogen using electrolysis.
This may sound exotic, but magnesium perchlorate is what the briny water at and near the surface of Mars appears to consist of, as seen for example when liquid droplets appeared on the legs of NASA’sPhoenixlander, which touched down in Mars’s far north in 2008. The Curiosity rover has also foundevidence of calcium perchlorate brinejust south of the martian equator.
Perchlorate salts are good at scavenging water from the driest of atmospheres, hence the droplets on the Phoenix lander’s legs. They can depress the freezing point of a liquid to as low as −70 °C, which prevents concentrated perchlorate brines from freezing even at Mars’s low surface temperatures. There are places where the appearance of dark, moist streaks is thought to be theseasonal flow of brine to the surface.
If you land where there is brine available, the new study argues, you could make as much oxygen as you like – provided you have unlimited brine and power. The breakthrough in the efficiency of this perchlorate brine electrolysis has to do with the make-up of the oxygen-producing electrode. For this, the study used a variety of a mineral calledpyrochlore, consisting in this instance of an oxide of lead and ruthenium. Pyrochlores have a wide range of technological applications, including, as in this case, as an “electrocatalyst” to make electrolysis faster and easier.
Practical options
It remains to be seen whether MOXIE-style electrolysis of martian carbon dioxide or pyrochlore-enabled electrolysis of martian brines proves the more practical way to make oxygen on Mars. The hydrogen from brine electrolysis is a bonus that you don’t get by electrolysis of carbon dioxide, and this could be used as rocket fuel as the study points out. Actually, if you want to do that, you’d need to use up the oxygen as the complimentary component of the fuel. But at least that gives you a choice: breathe the oxygen or use it in a hydrogen-plus-oxygen fuel mixture.
Neither option would be available during the several month long journey to and from Mars, for which recycling solutions would have to be found, as today on the International Space Station. These would also be important on the surface of Mars.
There is another way to replenish oxygen of course, which would be togrow plantsin the Mars base. These could absorb the carbon dioxide exhaled by the crew and liberate oxygen by photosynthesis. Crew members could also eat some of the plants, which would be a welcome source of fresh food.
This article byDavid Rothery, Professor of Planetary Geosciences,The Open University, is republished fromThe Conversationunder a Creative Commons license. Read theoriginal article.
Story byThe Conversation
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