NASA Designs 'Ice Dome' For Astronauts On Mars

An anonymous reader quotes a report from Phys.Org: The "Mars Ice Home" is a large inflatable dome that is surrounded by a shell of water ice. NASA said the design is just one of many potential concepts for creating a sustainable home for future Martian explorers. The idea came from a team at NASA's Langley Research Center that started with the concept of using resources on Mars to help build a habitat that could effectively protect humans from the elements on the Red Planet's surface, including high-energy radiation. The advantages of the Mars Ice Home is that the shell is lightweight and can be transported and deployed with simple robotics, then filled with water before the crew arrives. The ice will protect astronauts from radiation and will provide a safe place to call home, NASA says. But the structure also serves as a storage tank for water, to be used either by the explorers or it could potentially be converted to rocket fuel for the proposed Mars Ascent Vehicle. Then the structure could be refilled for the next crew. Other concepts had astronauts living in caves, or underground, or in dark, heavily shielded habitats. The team said the Ice Home concept balances the need to provide protection from radiation, without the drawbacks of an underground habitat. The design maximizes the thickness of ice above the crew quarters to reduce radiation exposure while also still allowing light to pass through ice and surrounding materials.

Re:Only in America...

[dbIII]

Just have to carry the water in supply ships

Someone hasn't been paying attention over the last few years.

Re:Only in America...

[Rei]

Arbitrary saline water is not "excellent for electrolysis", you'll end up destroying your electrolysis cells. Look at all the trouble they've had with the Elektron systems on the ISS, and that's under perfectly controlled conditions. Screwups are not acceptable on Mars. You can't just guess that things will be okay. For any potential ice resource, you need to have it very well quantified (and not just a tiny surface sample - and not just the water, but all of the solid matter it's mixed in with), so that engineers on Earth can create an accurate testbed for their proposed hardware to operate on.

Re, boring: have you ever seen the size of a TBM? Don't get me wrong, nuclear-powered Martian backhoes aren't exactly a dime a dozen, but that sure sounds cheaper than martian TBMs.

I have to agree with weird_w - the simplest means of radiation shielding is to use loose regolith (in regions where it's available in a deep enough layer... which aren't exactly rare, although they're not universal). Whether that's via bagging, binding with cement, binding with materials from Earth (a thermoplastic, epoxy, water, etc, optionally plus reinforcing fibers), or just simple loose dumping over a form, they're probably your easiest bet.

If you are advancing to the point where you're going to be doing in-situ water harvesting for electrolysis and drinking, however, something like the ice house is probably worth consideration. It does provide for much better human factors via transmission of (and fresnel concentration of) light, and allows for some limited agriculture (without requiring vast amounts of power generation for artificial lighting). It's easy to want to ignore human factors, but they're very real. Having people live their lives inside a cramped windowless can isn't exactly good for mental health or morale.

However, IRSU water is not a given. Pretending that harvesting of water is just "you go there and dig it up" is a vast oversimplification. To the point that even a lot of IRSU propellant proposals call for sending the hydrogen for the fuel from Earth even while they get the carbon and oxygen from the atmosphere. The atmosphere is a fairly constant, reliable, predictable fluid feedstock. The ground... isn't.

(And yes, technically you can get water vapor from the atmosphere, but the quantities it's available in are so tiny that most analysis writes off the concept due to the amount of air you'd have to move through the system per unit water recovered, and the mass of the system you'd need to do so)

Re:Only in America...

[Rei]

I assume you mean basalt fiber, not glass fiber. Quartz sand is not readily available on Mars.

Not every basalt is suitable for use in production of basalt fiber. I have no clue how well Martian regolith would suit, and I doubt anyone else does. Either way, it's a very energy intense process involving some pretty heavy hardware; you have to basically create a molten pool of basalt (aka lava) at about 1400C and blast it through tiny nozzles into air (which is extremely thin to begin with on Mars) moving at hurricane speeds.

Yes, the simulants like JSC Mars-1A are pretty poor. It's just sifted Pu’u Nene tephra. MMS is a bit better (not as weathered), but still, they just (roughly) match major elemental concentrations, they don't have any of the "Mars specific" things like hexavalent chromium, perchlorates, etc, nor do they guarantee particular mineral forms. And "roughly" is a key term to emphasize about the ratios. But for something where you're just going to be melting it down, that probably doesn't matter too much. Again, though, "Martian basalt", like basalt on Earth, is not a single universal thing; the dust from the particular site would need to be sampled and analyzed on its own.

Were you talking about fiber production for use as loose-fill reinforcing fibers (like are used in some types of concrete) or for making into cloth to make into bags? Either way it's probably just easier to send from Earth, at least in the early phases.