SEArch+ / ICON
With the huge cost of transporting materials, people and machinery into space, extraterrestrial construction concepts have to utilize local materials and versatile, compact technology. Designs like SEArch+ and ICON's 3D-printed lunar base (pictured) incorporate both -- their initiative, Project Olympus, uses moon dust as the main building material. Scroll through to see more amazing designs for space habitats.
SEArch+
Project Olympus isn't the first foray that SEArch+ has made into space habitat design. In 2019, the New York-based architects won first place in the third phase of NASA's 3D-Printed Habitat Challenge with Mars X House, designed with 3D-printing experts Apis Cor. Much like Project Olympus, this design uses Martian soil to construct a 3D-printed habitat, which blends seamlessly into the dusty red landscape.
SEArch+
In space, the main goal is to "protect the astronauts from extreme environmental conditions," like high levels of radiation, says SEArch+ co-founder Rebeccah Pailes-Friedman. The hourglass shape of Mars X House -- seen here being constructed by robots -- maintains the habitat's pressurized atmosphere, while shaded windows provide both natural light and radiation protection.
SEArch+/Clouds AO
In 2015, NASA confirmed the presence of water on Mars — opening up a world of possibilities for human habitats. The Mars Ice House, another concept from SEArch+, turns the ice into water to 3D print an external, transparent, protective shell. Water is an excellent natural barrier against radiation, and temperatures on Mars average around -81F (-63C), allowing the water to freeze and form a permanent ice structure.
NASA/SEArch+/Clouds AO
Pailes-Friedman says SEArch+ "designs from the human perspective," because during longer missions "human needs become paramount for mission success." While most designs for a habitat on Mars involve underground accommodation, this proposal allows natural light into living areas of the habitat. This innovative conservatory-like building would also house gardens and serve as a recreational space.
Monika Brandić Lipińska
Inspired by Russian nesting dolls, Testlab envisions a multi-layered moon base with modular pods beneath a protective membrane. Winner of the 2017 Moontopia Competition, the base includes compartments for sleeping, living and research that can be sized up and down according to requirements. The outer membrane is 3D-printed and shields the structure from radiation and meteorites, as well as capturing hydrogen atoms from solar winds to produce a system for oxygen and water production for the base.
Monika Brandić Lipińska
Maximizing natural light while protecting astronauts from radiation is one of the biggest design challenges in space architecture. Lunar Light House is 3D-printed with nano-cellulose, a super strong, translucent substance found in plants which could, potentially, be grown on the moon. The base would be coated in moon dust for extra radiation protection.
Monika Brandić Lipińska
While most architecture projects for the moon look at the practicalities of living, eating, sleeping and breathing in space, Arc' de Exploration proposes a monument for the first lunar civilization. Mimicking earthly landmarks like the Arc de Triomphe, the arch is designed to be seen from afar and beautifully frames the planet it orbits.
SOM / Slashcube GmbH
While most habitat proposals for the moon aim to house four astronauts, some look at scaling up. "Moon Village," a project by architects Skidmore, Owings and Merrill (SOM) in collaboration with the European Space Agency and Massachusetts Institute of Technology, conceptualizes a modular design with interconnected inflatable pods. A solid external frame -- rather than a solid central core -- allows each module to be used flexibly and protects occupants from the moon's harsh environment.
SOM / Slashcube GmbH
SOM has suggested placing the base at the moon's south pole. Little studied, this area is of interest to scientists, and looks like a good place to set up a lunar habitat: with continual daylight for more than 200 days a year and situated close to moon ice sites, it would allow access to water and solar energy.
ABIBOO Studio, SONet (Gonzalo Rojas & Sebastian Rodriguez)
Taking several giant leaps, international architects Abiboo have envisioned an entire Martian city for up to 250,000 inhabitants. Nüwa City is comprised of a network of tunnels and pod-like "macro-buildings" built into the steep cliff face. This offers protection from radiation and meteorites while still providing sunlight through sheltered windows.
ABIBOO Studio, SONet (Gonzalo Rojas & Sebastian Rodriguez)
Nüwa City is designed to be built from local materials, including carbon and other minerals. The plans include ideas for the production of food, oxygen and energy, as well as water processing. The city would initially be supplied by Earth but, ultimately, it would become self-sufficient and sustainable.
ESA / Foster + Partners
From the same architects who built Spaceport America comes another futuristic space building — this time, for Mars. Foster+Partners' speculative space base features a modular design, mixing 3D-printing with prefab inflatable structures, which can easily be extended.
ESA / Foster + Partners
Foster+Partners' Mars habitat would be powered by solar energy, while autonomous robots would 3D-print protective shells and fit inflatable habitat pods into them ahead of astronauts landing on the Red Planet. The habitats would be completed by the first human arrivals.
Bjarke Ingels Group (BIG)
Bjarke Ingels Group (BIG) conceived a simple but effective way to survive on Mars: live in a bubble. Giant inflatable biospheres create a pressurized habitat, with 3D-printed buildings, gardens and pavilions inside.
Bjarke Ingels Group (BIG)
While most space bases are purely theoretical, BIG adapted its design in 2017 for a potential Earth-bound prototype in the Emirati Desert outside of Dubai. If chosen for the project, Mars Science City would join Dubai's Mohammed Bin Rashid Space Centre (MBRSC) as an education and research center.
Bjarke Ingels Group (BIG) / ICON
BIG has continued developing 3D-printed space base concepts, and its latest project with ICON is backed by NASA. The donut-shaped habitat is packed with moon dust on the outside, to protect from radiation and meteorite impacts.
CNN  — 

The last time a person stepped foot on the moon was 1972. Now, the moon is back on NASA’s space agenda. This time around the agency isn’t just visiting – it’s planning to stay.

With its Artemis missions starting next year, NASA aims to have astronauts on the moon in 2024 and anticipates a permanent lunar base by the end of the decade. This would be the first habitat ever constructed on an extraterrestrial surface, and the challenges are unprecedented.

Sending a large quantity of construction materials to the moon would be expensive and time-consuming. But Texas-based startup ICON says it has a sci-fi solution – 3D printing a lunar base from moon dust.

ICON is working with NASA to develop technology that can turn moon dust into a concrete-like material, says co-founder and CEO Jason Ballard. Moon dust, also known as lunar regolith, is the sand-like topsoil that covers the moon’s surface, formed from minerals and tiny shards of glass created over millions of years as meteoroids hit the moon. It’s sharp, abrasive, and extremely clingy – the Apollo astronauts found it stuck to everything, including their space suits. There’s plenty of it, which means there’s a huge supply of raw materials if ICON is successful.

Bjarke Ingels Group / ICON
BIG's concept for Project Olympus includes donut-shaped buildings which could be entirely constructed with ICON's 3D printer.

The initiative is named Project Olympus after the largest-known volcano in the solar system – aptly conveying the mountain-sized challenge the team faces. But Ballard isn’t just shooting for the moon. By designing a lunar habitat, he hopes to make construction on Earth cleaner, faster and cheaper, too.

Project Olympus

ICON has been using 3D printing technology to build social housing in Mexico and Texas, since 2018. Using a concrete-based mixture called lavacrete, its Vulcan printer can print around 500-square-feet in 24 hours.

But the moon is a “radically different world,” says Ballard. From Earth, it looks like a serene, smooth, silver orb but it is subject to high levels of radiation, violent moonquakes, extreme temperature swings and frequent strikes by micrometeorites that crash through its thin atmosphere, he says.

And turning moon dust into building material is another huge challenge. The team is experimenting with small samples of moon dust in a lab – working out how to change its state with microwaves, lasers and infrared light, while using “little to no additives,” says Ballard.

Bjarke Ingels Group / ICON
The research area in ICON's proposed lunar structure is illuminated with smart lights that simulate day and night on Earth, to help astronauts retain a normal sleep-wake cycle.

ICON worked with two architectural firms, Bjarke Ingels Group (BIG) and Space Exploration Architecture (SEArch+), to explore the possibilities of 3D printing technology.

The team studied habitats in extreme environments, including the McMurdo Station in Antarctica and the International Space Station, and used their findings to create a range of lunar design concepts, says Ballard.

The architects had to consider how to create an environment that is safe as well as comfortable to live in, says BIG founder Bjarke Ingels.

The proposal by SEArch+ features a tall, multi-story structure with protective 3D-printed petals shielding a core that would be built on Earth, while BIG designed a circular structure which could be entirely printed on the moon.

BIG’s design includes a visible membrane of water padding the walls of the bedroom – “a good insulant against radiation,” says Ingels – which will give astronauts extra protection while they sleep.

The radiation means that windows must be kept to a minimum, so Ingels carefully chose the location of the building’s only one – which always faces Earth.

SEArch+ / ICON
SEArch+ imagined a base "that will allow astronauts to frequently come and go from the surface," with landing pads, roads, sheds and habitats says co-founder Rebeccah Pailes-Friedman.

A “double shell” structure and exterior latticework, which can be packed with loose lunar dust, provide additional protection from radiation and meteorites, says Ingels.

In addition to living and working spaces for astronauts, the lunar base would need to incorporate landing pads, roads and storage sheds. Human presence in space has been “dominated by engineering” so far, says Ingels. With multiple industries working together he hopes that the first permanent structure on the moon can be “aspirational” in design as well as an engineering marvel.

A gateway to the galaxy

NASA began exploring 3D printing as a possible space construction technology with the launch of the 3D-Printed Habitat Competition in 2015. Both SEArch+ and ICON took part in the initiative, with SEArch+ placing first for its design of the Mars X House.

With the Artemis missions launching next year, NASA’s first step towards a lunar habitat is the “Gateway,” a space station in the moon’s orbit, says spokesperson Clare Skelly. Astronauts will live and work on the Gateway and shuttle to the moon, staying in their landers for up to a week.

ICON
ICON's 3D-printer, Vulcan, draws the outline of the building one layer at a time. It can print up to 500 square feet in 24 hours.

Its goal, however, is a permanent base, from which to explore the moon in more depth and and test technology for human survival in space. NASA wants to construct facilities to house four astronauts for up to a month, says Skelly. It’s an essential first step to Mars – and beyond.

Skelly says it has not yet been decided if the lunar habitat will be constructed using 3D printing, but “NASA could award ICON additional funding” and might give the company the opportunity to test its technology on the lunar surface.

Using moon tech on Earth

Ballard is optimistic about the technology’s Earthbound potential, too. He believes the findings from Project Olympus could help to solve the global housing crisis.

As a relatively new technology, there’s little definitive data on the advantages of 3D printing in construction. However, a 2020 review notes that it could reduce construction waste by 30% to 60%, labor costs by 50% to 80%, and construction time by 50% to 70% which would make building cheaper, faster and more sustainable.

Joshua Perez / ICON
ICON's first 3D construction project was a collaboration with non-profit New Story in Mexico, to build a social housing community for people who had lost their homes in natural disasters.

While the technology is largely used on bespoke projects right now, Ballard hopes that the possibility to use “rawer, more direct, local materials” could open up more opportunities for 3D construction – which could be transformative for some of the 1.6 billion people still in need of adequate housing on Earth.

“It’s kind of a funny thought,” he says, “but it just may turn out that the answers to our problems on Earth are on the moon or Mars.”