The other reason water is the most important resource on Mars

There are lots of potential uses for a Mars colony.

by Andy Tomaswick
Donald Iain Smith/Photodisc/Getty Images

There are lots of potential uses for a Mars colony. It could be a research outpost, mining colony, or even a possible second home if something happens to go drastically wrong on our first one. But it could also be a potential source of what is sure to be one of the most valuable elements in the space economy — hydrogen.

A new paper from Dr. Mikhail Shubov at the University of Massachusetts Lowell discusses such an eventuality. Hydrogen is useful in myriad applications. From creating water to exploding as rocket fuel, the most abundant element in the universe sure has many uses. The problem is, it’s relatively hard to get access to in the broader solar system.

UT video discussing possibilities for a Martian colony.

There is plenty of it in Jupiter or even the Sun, but extracting that light of material from those enormous gravity wells is not particularly cost-effective. Smaller orbital bodies, such as asteroids, have some water that could be used as a hydrogen source, but they are not large enough to provide all of the solar system’s needs.

One particular place in the Solar System does have an abundant potential source of hydrogen and a relatively weak gravity well — Mars. Admittedly the hydrogen on the Red Planet is in water form. However, hydrolysis is a fairly common reaction that requires power and has the added benefit of producing pure oxygen, which is valuable in its own right.

You could feed a lot more than 10,000 people on Mars, according to this UT video.

Water has plenty of other uses on Mars, though, not the least of which would be sustaining any colony that would be looking to perform hydrogen export in the first place. However, water recycling will likely be a common technique in the early days of any colony, so once enough water is collected, additional input would only need to match the losses of any water reclamation system.

While it might not seem like it at first glance, Mars has a lot of water. Satellites have detected more than 5 million cubic kilometers of ice on or near its surface. If even a tiny fragment of that is exploited for water consumption at a colony, it could indefinitely support tens of thousands of residents.

In-situ resource utilization will be a key component of any sustainable Martian colony. This UT video discusses the concept.

Dr. Shubov suggests doing precisely that — but only after the surrounding economy has grown enough to warrant mass use of hydrogen in space. That includes not only orbital infrastructure, like the Gateway space station but also the Mars colony itself.

Throughout the paper, one suggestion that he repeats is only starting a hydrogen extraction process when approximately 10,000 people are resident in a future Martian colony. He even goes so far as to estimate the total amount of steel and plastic necessary to build a large enough colony to support all those colonists.

Those aren’t the only stipulation, though — having launch infrastructure on the planet itself is key to making the economic argument to ship hydrogen off-world. One potential infrastructure solution is a mass driver — a type of very long rail gun that could potentially launch packages of hydrogen straight from the Martian surface into orbit.

While there are even plans to build such a system on Earth, the physics of Mars is much more amenable to the large-scale engineering needed to build mass drivers or other infrastructure that could significantly decrease orbital launch costs.

It’s great to get the hydrogen into orbit around Mars, but where does it go from there? To Earth is the most likely answer, at least until other bases in the solar system start to require their hydrogen. Getting a significant amount of gas to Earth will require not burning some of that fuel. However, various potential cyclical solutions have been discussed, the most famous – the Aldrin Cycler.

No matter the solution selected to get the valuable rocket fuel back home, Dr. Shubov’s argument of how such a hydrogen export system could work. We’re still very far from any need for such a hydrogen market, even on Earth, let alone in space. But that will never stop some dreamers from coming up with scenarios that could fundamentally alter the economics of the solar system.

This article was originally published on Universe Today by ANDY TOMASWICK. Read the original article here.

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