How to colonize the Moon?
After the successful Apollo missions that put humans on the Moon starting 1969, the ongoing dream was that there would soon be a permanent human settlement on our only natural satellite. Best captured in science fiction works like the classic 2001: A Space Odyssey, colonization of the Moon was seen as somewhat inevitable. But as it turned out, the last time humans went beyond low-earth orbit (LEO) was the Apollo 17 mission in 1972. Sad times we live in.
The Soviet space program had some serious proposals for a permanent moon base, one of which was Zvezda. The plan was to use the super heavy-lift launch vehicle N1-L3 (the Soviet Union’s competitor to America’s Saturn V) to deliver tons of material for use in habitable modules on the lunar surface. Each of the modules were to be launched separately. The habitable modules were to be docked on a movable train-like platform, to allow exploration or repositioning of the moon base. The concept unfortunately died with the failed Soviet human lunar programs.
NASA also had a lunar base concept in the 1980s which went nowhere due to fading interest in the idea and focus on other areas such as the Space Shuttle program.
Why the Moon is a great place to start
The Moon has no atmosphere and is basically a dead land. Mars definitely is a less hostile place better suited to colonization. Elon Musk’s SpaceX has its sights set on it too. But the Moon’s big advantages arise out of its proximity:
- The Moon can be reached in a matter of days, allowing for faster development and use of fewer resources.
- Light takes only 1.3 seconds to reach the Moon, allowing for near real-time communications and remote control of machines, which would be impossible on any other major astronomical body.
- The short travel time to the Moon would allow for a quick emergency supply of materials or an urgent crew evacuation situation. Mark Watney from The Martian would have appreciated both of these.
On the other hand, it takes months to reach Mars, which also has a round-trip communications delay of 8 to 40 minutes and doesn’t allow remote control of machines.
The Moon’s proximity makes it a stepping stone on our journey to becoming an interplanetary species. The question is, how? In such hostile conditions, how are we ever going to make a permanent home?
#1: Powering habitats on the Moon
The daytime temperatures on the lunar surface exceed 100° Celsius and nighttime temperatures can dip as far as -180° Celsius. Solar panels can be used to power moon colonies during lunar day; however powering the colonies during a lunar night — equivalent to 14 Earth days — is an issue that needs to be solved.
Enter the peaks of eternal light. The Moon’s equator is tilted only slightly by ~1.5 degrees to the orbit of the Earth around the Sun. Its orbital motion is such that some peaks near its poles are constantly facing the Sun, thereby making them peaks of eternal light.
Well, eternal here means as long as the Sun shines or gobbles up the Moon when it becomes a red giant. The Japanese spacecraft SELENE identified four peaks near the lunar south pole which receive sunlight more than 80% of the time.
NASA’s Clementine orbiter also discovered the nearby Malapert mountain was illuminated by sunlight nearly 90% of the time. Similar peaks are found at the lunar north pole. These areas will thus have near constant sunlight to power the moon colonies.
#2: Permanent shadow regions as a source of water
Similar to the regions of eternal light, there are regions near the poles which are permanently in the dark. This is usually due to the peaks shadowing those regions from sunlight or deep craters where the sunlight simply does not reach. These permashadow regions in the south pole have been observed by NASA’s Lunar Reconnaissance Orbiter (LRO).
Discovery of water ice in the permashadow regions
Having not received any sunlight for nearly 2 billion years, these permashadow regions are an excellent trap for volatiles (chemicals which would vaporize in space if exposed to sunlight), including water. India’s Chandrayaan-1 spacecraft, using NASA’s Mini-SAR radar, found more than 40 craters containing water ice on the lunar north pole. It is estimated that there could be 100 billion kg of water ice in these regions. NASA’s LCROSS spacecraft detached the Centaur upper stage to deliberately impact one of the permashadow regions on the lunar south pole.
The impact plume was estimated to have 100 kg of water ice, among other volatile substances including carbon dioxide, methane and ammonia. The water ice could potentially be harnessed to supply water for consumption in Moon colonies.
#3: Farming on the Moon
Since areas near the lunar poles are in constant sunlight/darkness, rotating farms with temperature control systems can be built such that they are exposed to sunlight for half an Earth day, on and off. Other needs for the plants, like insects for pollination and radiation protection, can be provided manually. The 1991 paper, “Lunar farming: achieving maximum yield for the exploration of space”, explores these concepts.
NASA Technical Reports Server (NTRS) - Lunar Farming: Achieving Maximum Yield for the Exploration…
A look at what it might be like on a lunar farm in the year 2020 is provided from the point of view of the farmer.
With such a system in place, even a quarter of a hectare of land can feed ~50 people, a good start for a small but permanent settlement on the Moon.
#4: Building lunar habitats with adequate protection
The Moon lacking an atmosphere means humans need to be protected from damaging solar radiation and cosmic rays. The Moon is also constantly bombarded with tiny meteorites which can severely damage the habitats as, with no atmosphere, they aren’t slowed down or burned up on their way.
Building modules in the craters of the permashadow regions provides partial shielding from these problems. Furthermore, the habitat modules can be covered with lunar regolith mixed with some concrete-forming materials, which have some interesting structural properties, as revealed by an Apollo 16 lunar soil experiment. Another way of protecting habitats could be to create an electrostatic radiation shield, a concept being tested by one of the Lab2Moon missions here at TeamIndus.
Earth-inspired solution to a space problem
Deadly radiation stands between man and the cosmos. Three engineering students are working on a material-free mechanism…
The habitable modules for humans will be similar to the closed-dome lunar farms with atmospheric control systems. There are lots of ideas on how such modules might be built. One such concept — a flexible, inflatable module — has been proposed by NASA. A big enough inflatable habitat could accommodate the needs of a dozen astronauts living and working on the surface of the Moon. The Lab2Moon mission LunaDome is going to test one such atmospheric control system on board our lander.
All the above technologies combined can be the basis for a permanent human outpost outside our Earth. The first lunar colony doesn’t have to be grand, it just needs to work for a dozen people.
Think of the first lunar colony as an International Space Station on the Moon.
Colonizing the Moon would allow us to explore and develop technologies to help us move ahead as a space-faring species. A solid working ground to push the human race forward, with more of our strengths and less of our weaknesses. Who’s interested?
Those who want to take the Moonshot
- Japan wants to land a human on the Moon by 2030.
- China’s lunar exploration program may see them land a taikonaut on the Moon by 2036.
- Russia has plans to build a lunar colony with 12 cosmonauts by 2030.
- A growing interest from private space companies is expected due to the Moon’s accessibility.
One of the major difficulties beyond the technological and resource aspects of lunar colonization is in the potential for national, political and private interests to conflict. Enter Jan Woerner, director of the European Space Agency (ESA),with his idea of an open access Moon Village.
The Moon Village Association
The Moon Village Association is a non-profit organization that aims to coordinate the efforts between multiple space agencies, be it governmental or private. The aim is to avoid unnecessary use of resources by allowing these organizations to collaborate with each other. The project can also help manage and resolve conflicts of interest in a way that benefits multiple parties.
The first Moon Village workshop was successfully carried out in November 2017, an initial call to those interested and involved in the dream of going to the Moon. TeamIndus was there too and was interested in the possibilities of such a visionary collaboration.
To the Moon and beyond
Up there in the sky lies the dream that you can see everyday as it waxes and wanes. A dream that is yet to be realized, but one we are moving towards. It’s a dream that we must fight for together if we are to become a space-faring species. As Carl Sagan said:
All civilizations become either space-faring or extinct.
P.S.: This piece explores just one of the many possibilities of colonizing the Moon. The points discussed here are chosen to complement one another, to give one of many 'complete' solutions. Using nuclear fission/fusion as a source of power is also an option. Another promising region for habitats are lunar lava tubes.
Brandon Weigel has written a follow-up of this article detailing how a lunar base will be provided with water supplies from the permashadow regions. The solution is to build the largest rover ever to go on an extraterrestrial object till date. Catch the article here.
Edit: We were thrilled to get a reply from @Andyweir (author of The Martian and Artemis:
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