Autonomous conversion of asteroids into rotating space settlements

Artist impression of a rotating space settlement constructed from an asteroid. Credits: Bryan Versteeg, spacehabs.com

When Gerard K. O’Neill first proposed building enormous rotating space settlements at the Earth-Moon Lagrange points back in the 1970s he envisioned many space shuttle flights to launch the initial equipment and people into space. He thought that mass drivers placed on the Moon would be an efficient and cost effective mechanism for lofting copious amounts of lunar regolith needed for radiation shielding to protect colonists aboard the settlements. Alas, the economics of the shuttle did not work out back then, as reusability (among other things) was not ready for prime time, making launch costs a show stopper. Also, O’Neill thought that hundreds of people would be working under weightless conditions in space to fabricate the settlements. This was problematic because of the health hazards of exposure to radiation and microgravity.

All three problems can be solved according to David W. Jensen in an article posted on the ArXiv server. He envisions restructuring an asteroid into a spin gravity space settlement using self replicating robots to process asteroid materials in situ. High launch costs would be solved with a single modest-size probe containing a small number of seed robots that fashion more robots, tools and equipment. This approach bootstraps the colony fabrication through self replicating machines and in situ resource utilization.

“The restructuring process improves the productivity using self-replication parallelism and tool specialization.”

By removing humans from the initial asteroid processing activities, health risks from radiation and the deleterious effects of microgravity would be eliminated. Restructuring of the asteroid would take about a decade, after which colonists would have a rotating space settlement the size of a Stanford Torus providing Earth normal gravity and a safe living space shielded from radiation, ready for buildout and eventual occupation.

Cutaway view of a Stanford Torus space settlement. Credits: Rick Guidice / NASA

The key to this approach is self replication of robots delivered in the initial seed payload which significantly reduces costs by launching only one rocket to the target asteroid. The first machines sent are called replicators, or spiders for short. Four of these spiders with a minimum of supplies use the raw materials of the asteroid to make thousands of copies of themselves plus additional helper machines (tools and equipment). The spiders and helpers cooperate to produce end products of construction materials and the colony structures.

Jensen does not assume total self-replication, meaning that the robots do not need to make complete copies of themselves. A small percentage of more complex mechanisms such as microprocessors are provided in the initial payload as supplemental “vitamins” to finish out the machines. The intent is to minimize the need for humans in the initial construction phase. The objective is to fabricate a basic scaffolding for a rotating space settlement with access to an abundant storehouse of volatiles and metals. The final enclosed structure would then support migration of colonists who would complete construction and add more advanced manufacturing technologies such as solar cell production and microelectronics. As SSP has explained previously, complete closure of self-replicating machines is very challenging, but is not needed in this case.

The technology has wide applications and could be applied to Earth’s desserts, on the surface of the Moon or Mars, or even on the satellites of Jupiter and Saturn.

“We plan to apply and study these concepts for use in lunar, Titan, and Martian environments.”

Jensen’s restructuring process could complement or be combined with other asteroid mining architectures such as the University of Rochester’s approach which builds spin gravity cities starting with a carbon fiber collapsible scaffolding completely encapsulating the target asteroid. As the process matures it could be applied to even larger bodies such as the asteroid Ceres eventually combining settlements into a mega satellite community as envisioned by Pekka Janhunen.

“The equipment and process are scalable and … create a
space station structure that can support a population of nearly
one million people.”

Self-replicating “living” machines for lunar settlement

Conceptual illustration of a self-replicating machine. Source: Wikipedia

In a 2020 paper in the journal Biomimetics, Alex Ellery who heads the Space Exploration Engineering Group in the Department of Mechanical & Aerospace Engineering at Carleton University, Ottawa, lays out a case for engineering mechanical systems that emulate biological life in the same vain as a Von Neumann universal constructor. This concept, conceived by the Hungarian-American mathematician John von Neumann in 1940s prior to the invention of the computer, is a machine that can make copies of itself given a set of instructions, sufficient materials and a source of energy.

Ellery begins by examining theories on the origin of life on Earth to distill down the essence of how inanimate material was transformed into living systems. He then goes on to define the basic characteristics of how organisms use energy to process materials to evolve and reproduce. Applying these principles to mechanical systems he envisions bioinspired machines be used to propagate self-replicating factories on the Moon in a lunar industrial ecology. Materials mined in situ by robots would be processed using solar energy via automated additive manufacturing processes analogous to living organisms reproducing to expand the facility.

“Adopting the notion of a biological ecosystem, we can envisage a modest self-sustained metabolism.”

In an examination of what life is, Ellery makes the analogy between ribosomes, the basic macromolecular machine that performs protein synthesis in living cells, and a 3D printer called the Replicating Rapid Prototyper (or RepRap), a key element of his research. Through additive manufacturing this device can print some of its own plastic components.

RepRap 3D printer comprising a Cartesian robot with extruder head (Figure 2 in the paper) capable of printing copies of some of its own plastic components.. Credits: Alex Ellery

Eventually, Ellery’s goal is for the device to be able to fabricate most of its own parts including the metal components. However, a fully autonomous self-replicating machine will required considerable advancements in artificial intelligence and automation. Initially, prefabricated complex components such as electronic circuitry, actuators, and sensors may be supplied independently as “vitamins” from Earth and assembled automatically during fabrication to enable automatic manufacture of the robots. Ellery introduces his team and describes his research at Carlton University in this short video.

Self-replicating factories designed for the production of space settlement infrastructure have been covered previously by SSP. Hybrid approaches that include humans in the loop to guide the process may be a near term solution until AI and robotic technologies become fully autonomous.

Some have postulated that if Von Neumann probes have been used by alien civilizations to colonize the galaxy there may be ways to detect them.

Self replicating factories for space settlement

Artist’s illustration of a self replicating factory near an asteroid and serviced by a SpaceX Starship. Credits: Michel Lamontagne / Principium

The technology of self replicating machines has been gradually progressing toward maturity over the last few decades. The Space Studies Institute recognized this key enabler of space settlement as far back as the 1980s and covered the topic frequently in its newsletter updates. Now Michel Lamontagne has provided a status update in the latest issue of Principium. On page 50, he highlights the history of self replicating factories, provides a vision for the evolution of the concept for production of space settlement infrastructure and gives a summary of recent developments in key areas of research such as additive manufacturing, machine learning and cheap access to space that will be enablers of this space based industry.

The first factory will be built on the Moon after deep learning simulations prove the concept on Earth. Eventually the more autonomous versions would migrate to Mars and then to what may be the best suited location, the asteroid belt which “…may be the ultimate resource for space settlement construction.” Lamontagne believes “These factories would then follow humanity to the Stars, after having helped to build the infrastructure required for the occupation of the solar system and for Interstellar travel.”

Artist’s rendering of an early self replicating factory on the Moon with SpaceX Starships serving as basic construction elements. Credits: Michel Lamontagne / Principium

Worldships for interstellar space settlement

Image of an interstellar Worldship. Credits: Michel Lamontagne / Principium, Issue 32, February 2021

The feasibility of Worldships has been covered previously on SSP by The Initiative and Institute for Interstellar Studies via Principium. A new article by Michel Lamontagne on page 29 of the most recent issue examines the concept from a perspective of an interplanetary society which has harnessed fusion energy and life support systems for space settlements, while reducing costs through self replicating factories.

Such a starship is envisioned to use a deutrium/He3 fusion drive to accelerate to 1% of the speed of light completing a journey to Alpha Centauri in about 430 years. The author envisions a fleet of 3 or 4 (or more) Worldships housing about 1000 passengers each in rotating torus habitats 1,200m in diameter with artificial gravity.

Image of the interior of a worldship habitat. Credits: Michel Lamontagne / Principium, Issue 32, February 2021

Self replication is the key to this architecture. Lamontage explains: “If fully self replicating systems exist at the departure of the mission, Sprinter starships carrying self replicating machines can be sent at the same time as the Worldship flotilla departs. The Sprinters will arrive centuries before the Worldships, and the self replicating machines will have ample time to create multiple habitats, and perhaps begin to seed them with simple life forms.”

Lamontage cautions that the needed AI technology and practical self replicating machines may be more difficult to develop than predicted. The Worldship habitat ecosystems may encounter instabilities over centuries-long journeys leading to eventual breakdown of life support systems. Finally, rapid technological advances may lead to advanced propulsion schemes or other opportunities that would make a Worldship obsolete before getting started.

Detection of alien Von Neumann micro probes in the galaxy

You Should Know What The Fermi Paradox is Before Reading The Dark Forest | Tor.com
Artist concept of Von Neumann probes. Credits: tor.com

A common theme in science fiction is the application of John von Neumann’s concept of self replicating machines to colonize the galaxy. Now in a recent paper posted on the arXiv preprint server, Z. Osmanov has analyzed the spread and potential for detection of tiny versions of these robots as they move through our galaxy’s molecular hydrogen clouds harvesting material to reproduce. Calculations show that swarms of the probes would emit energy in the infrared part of the spectrum and might be bright enough for potential detection by the search for extraterrestrial intelligence (SETI).