If mankind is truly going to become a multiplanetary species as a lot of us aspire to, conventional ideas involve hauling tons of supplies from Earth to the Red Planet to establish civilization there. It is, without a doubt, a rough mission that requires exceptional people to go with all the risks that come with the mission. Comparatively, migrating between places on Earth is nothing. The air is safe to breathe, or more correctly, if you know how to treat the air in one hemisphere, you know how to treat it everywhere else on Earth. On Mars you don't even have air. Then there's building shelter. There are no trees on Mars so something like a log cabin isn't possible. Can something like concrete be made there, and buildings made from that? Bricks of some sort?
So what if early astronauts, early settlers, could bring something that's light but could create materials that can be built into useful things?
In a potential milestone for space exploration, scientists have successfully grown algae under simulated Martian conditions using equipment made from biodegradable bioplastics — a step that could bring long-term space colonization closer to reality.
As interest in human missions to Mars grows, scientists are focusing on how to sustain life in space without constant resupply from Earth. A team of researchers led by Robin Wordsworth of Harvard University demonstrated that green algae can not only survive but thrive inside bioplastic chambers designed to mimic the extreme environment of the Red Planet.
The idea is using bioplastics to grow more bioplastics that can be used to make useful things. Wordsworth puts it like this: "If you have a habitat that is composed of bioplastic, and it grows algae within it, that algae could produce more bioplastic. So you start to have a closed-loop system that can sustain itself and even grow through time." Mars missions don't need to transport supplies, the algae grows from CO2 in the Martian atmosphere.
In laboratory tests, Wordsworth and his team cultivated a common type of green algae called Dunaliella tertiolecta inside a 3D-printed chamber made from polylactic acid, which is a biodegradable plastic derived from natural sources. The chamber was engineered to replicate the thin, carbon dioxide–rich atmosphere of Mars, which has a surface pressure less than 1% that of Earth.
Despite these extreme conditions, the algae were able to perform photosynthesis, according to the statement.
Close-up of bioplastic habitat with algae growth. (Image credit: Harvard University)
The latest proof of concept experiment builds on earlier work by Wordsworth’s team, which showed that silica aerogels could replicate Earth’s greenhouse effect to support life in cold, low-pressure environments. By combining algae chambers for bioplastic production with aerogels for heat and pressure regulation, the researchers say they are making real progress toward self-sustaining space habitats.
The answer to not having forests to harvest wood from is to make your own wood from cellulose harvested from little Erlenmeyer flasks like this one.
Or, how about this, SiG - an electrically powered boring machine that runs off a small packaged reactor? Going underground also provides the benefit of some radiation protection. The tunnels and/or chambers could have strength linings applied if necessary.
ReplyDeleteIf we're going to dream, I want to dream big.
That's already being talked about and planned for. Then there's the robots that Tesla (?) is manufacturing. The talk is to send them to do the hard, dangerous work of getting things like the first underground habitats built.
DeleteI would say something like "This is groundbreaking, I wonder how they thought of that?"
ReplyDeleteExcept, well, sci-fi authors have been writing about this for at least the last 60 years.
And I've heard how algae would make our food, make our fuels, make our plastics and make our closed-loop spacecraft atmospheres for about, oh, 50 years.
Louis McMasters Bujold, in "Ethan of Athos," talks about Klein Station, a huge space habitat, that has algae purifying the habitat's atmosphere and balancing the CO2/O2 levels. To keep the algae from taking over, they use large 'newts' that feed on the algae. To keep the newts from taking over, they harvest the newts for food. To keep the biological waste from taking over, they feed some of the biological waste to the algae...
I mean, none of this is new at all. But good on researchers for actually doing something rather than talking about it.
"Let them eat bugs" in the immortal words of Our Betters!
DeleteOr do you think those "Betters" will disappear if we move off-world?
Douglas Adams told us how to address that in Hitchhiker's Guide to the Galaxy. They told "the betters" that the current ships to leave the planet weren't good enough for them, but their much better ships would be there "next week" or something and then everyone else left.
DeleteBeans - I vaguely remember a company on the Cape doing experiments on growing plants with the thought of something like that station. This was years before I worked on stuff for the ISS so "lots of years" before the ISS got up there. I think the company was called Bionetics.
DeleteWhat happened to the space wheel that would be large space stations with artificial gravity provided by the wheel's rotation as they worked their way through the planets? The wheels were supposed to have hydroponics, fish, fowl and beast along with a host of engineering stations to build what was needed or desired? Now we're back to eating algae.
ReplyDeleteDave
"large space stations with artificial gravity provided by the wheel's rotation"
DeleteAn idea that has never been tested at any scale, but everyone just **knows** it will work. As always in engineering, "it depends" and "everything is a tradeoff."
There's a private space station company called Vast that's working on testing some ideas that will be launched by SpaceX. But those have to be small because of the weight limits that can be launched.
The problem, of course, is a station that's rotating has to be strong enough to survive the rotation, which depends on how fast the rotation is, which depends on the size. If the station is too small, the gravitational gradient across your body might make motion sickness horrific. The bigger it is, the more expensive to launch. Like the ISS just plain looks rickety. Try to rotate that and it disassembles itself.
And microgravity has been a major pro for space at this time. Many things work better without significant g-ification.
DeleteWhen humans made craft to cross the at the time unknown oceans they used well proven technology and had the advantage they could at least breathe the air and harvest rainwater and fish.
ReplyDeleteI'd like to see this sort of critically important technology be proven here on earth in mass production to figure out bugs like needing "newts" to deal with overgrowth and such.
Its interesting how good Sci-Fi leads the way again.
Michael
Building a planetary infrastructure out of popsicle sized sticks ... doable, guess ... gonna require a lot of 8 year olds though.
ReplyDelete