Sustainable space commerce and settlement

Artist impression of a sustainable settlement on the Moon. Credits: ESA – CC BY-SA IGO 3.0

Dylan Taylor of Voyager Space Holdings recently wrote an article in The Space Review on sustainable space manufacturing. He makes a convincing case that long-duration space missions and eventual human expansion throughout the solar system will require radical changes in the way we design, manufacture, repair and maintain space assets to ensure longevity. In addition, the cost of lifting materials out of Earth’s deep gravity well will drive sustainable technologies such as additive manufacturing in space and in situ resource utilization to reduce the mass of materials needed to be launched off our planet to support space infrastructure. In-space recycling and reuse technologies will also be needed along with robotic manufacturing, self-reparability and eventually, self-replicating machines.

But there is more to the philosophy of sustainability and its impact on the future of space activities. According to the Secure World Foundation (SWF), sustainability is essential for “Ensuring that all humanity can continue to use outer space for peaceful purposes and socioeconomic benefit now and in the long term. This will require international cooperation, discussion, and agreements designed to ensure that outer space is safe, secure and peaceful.” Much of the discussion centers around the problem of orbital debris, radio frequency interference, and accidental or irresponsible actions by space actors. SWF is active in facilitating dialog among stakeholders and international cooperation.

The National Science and Technology Council released a report in January called the National Orbital Debris Research and Development Plan. To address the issue, there are several companies about to start operations in LEO to deal with the orbital debris or in-orbit servicing. Japan based Astroscale just launched a demonstration mission of their End-of-Life Services by Astroscale (ELSA) platform to prove the technology of capturing and deorbiting satellites that have reached their end of life or other inert orbital debris.

Image of the Astroscales ELSA-d mission showing the larger servicer spacecraft releasing and preparing to dock with a “client” in a series of technical demonstrations, proving the capability to find and dock with defunct satellites and other debris. Credits Astroscale.

Even financial services and investment houses like Morgan Stanley are pushing for sustainability to reduce the risks to potential benefits emerging from the Newspace economy such as remote sensing to support food security, greenhouse gas monitoring, and renewable energy not to mention internet access for billions of people.

Sustainable operations on the Moon are being studied by several groups as the impact of exploration and development of Earth’s natural satellite is considered. Lunar dust when kicked up by rocket exhaust plumes could create hazards to space actor’s assets as well as Apollo heritage sites. SWF, along with For All Moonkind, the Open Lunar Foundation, the MIT Space Exploration Initiative and Arizona State University have teamed up on a project called the Moon Dialogs to advance interdisciplinary lunar policy directions on the mitigation of the lunar dust problem and to shape governance and coordination mechanisms among stakeholders on the lunar surface. SSP’s take on lunar dust mitigation was covered last July.

These few examples just scratch the surface. NASA, ESA and the UN Office for Outer Space Affairs have initiatives to foster sustainability in space. Humanity will need a collaborative approach where public and private stakeholders work together to ensure that the infrastructure to support near term commercial activities in space and eventual space settlement is both durable and self-sustaining.

The long-term sustainability of space. Credits: ESA / UNOOSA

ArmorHab mission architecture for Mars Colonization

ArmorHab transport habitat configured for artificial gravity. Credits: Dark Sea Industries LLC / University of New Mexico / The Mars Society

The innovative ArmorHab mission architecture was presented at the Mars Society Conference in 2016. This novel approach should be considered as part of a strategy for settlement of the Red Planet. The concept integrates several engineering solutions for habitat design to address radiation protection, life support, and transportation while leveraging in situ resource utilization to enhance crew health, safety and reduce costs.

The basic building block of the architecture is a cylindrical Mylar shell wrapped in superconductive tape providing radiation protection through emulation of a magnetosphere. This structure is encased in a protective aerogel for strength and insulation including layers of water ice to further protect the crew from micrometeorites and algae bioreactors for scrubbing carbon dioxide for life support.

ArmorHab wall structure with superconducting tape for radiation protection and algae bioreactors for life support. Credits: Dark Sea Industries LLC / University of New Mexico / The Mars Society

Leveraging Buzz Aldrin’s Mars Cycler invention, the plan starts by building out infrastructure in cislunar space including automated factories on the Moon, then expanding out to Mars with space stations, cycling habitats and connecting “trucks” to provide transport to and from the surface of each destination.

Illustration of cycler model showing six TransportHabs, three space stations and a Mars Truck. Credits: Dark Sea Industries LLC / University of New Mexico / The Mars Society

Lunar Pantheon

Lunar Pantheon Habitat with circular 50 meter wide growing area. Credits: Nick Woolf and Roger Angel / Philosophical Transactions of the Royal Society A

A novel concept for a lunar polar settlement built like the ancient Roman Pantheon has just been published in the Philosophical Transaction of the Royal Society A. The stone structure, making full use of local in situ resources, would harness focused solar energy for construction, food production and atmospheric revitalization. The habitat would provide life support for at least 40 people with a greenhouse as large as 2000 square meters with crops illuminated by focused sunlight through a top circular oculus.

ESA’s Biorock experiment demonstrates microbe extraction of rare Earth elements from simulated regolith aboard ISS

ESA astronaut Luca Parmitano loads microbes into the Kubik centrifuge facility on the International Space Station. Credits: ESA

A research team at the University of Edinburgh in the UK has just published an analysis of data from an experiment on the International Space Station that could lead to “biomining” on Mars or an asteroid. Published in Nature Communications on November 10, Cockell, C.S., Santomartino, R., Finster, K. et al.* present experimental results demonstrating microbiological leaching of rare Earth elements from basalt rock, an analogue for much of the regolith material on the Moon and Mars. Called BioRock, the ESA sponsored experiment examined three species of microorganisms under variable gravity conditions in the Kubik centrifuge facility located in Europe’s Columbus module on the ISS.

This technology is a significant breakthrough for in situ resource utilization. By “living off the land” on the Moon, Mars or an asteroid, space settlers could have an available source of valuable materials used in electronic devices and many other high-technology applications. These rare Earth elements and the traditional heavy mining equipment needed to extract them would not have to be launched from Earth, significantly reducing transportation and processing costs. Positive results were found under Earth gravity, Mars gravity and microgravity conditions. The authors conclude that the experiment “…shows the efficacy of microbe–mineral interactions for advancing the establishment of a self-sustaining permanent human presence beyond the Earth and the technical means to do that.”

* BioRock study Authors: Charles S. CockellRosa SantomartinoKai FinsterAnnemiek C. WaajenLorna J. EadesRalf MoellerPetra RettbergFelix M. FuchsRob Van HoudtNatalie LeysIlse ConinxJason HattonLuca ParmitanoJutta KrauseAndrea KoehlerNicol CaplinLobke ZuijderduijnAlessandro MarianiStefano S. PellariFabrizio CarubiaGiacomo LucianiMichele BalsamoValfredo ZolesiNatasha NicholsonClaire-Marie LoudonJeannine Doswald-WinklerMagdalena HerováBernd RattenbacherJennifer WadsworthR. Craig Everroad & René Demets 

Eta Space snags $27 million Tipping Point award to study space based cryogenic propellant depot technologies

Artist rendering of LOXSAT 1, a demonstrator satellite for a cryogenic oxygen fluid management system. Credits: Eta Space

A small Florida Space Coast start up founded by NASA employees called Eta Space was just awarded a 2020 NASA Space Technology Mission Directorate “Tipping Point” contract to develop the first low Earth orbit cryogenic propellant depot. Management of cryogenic fuels is a key technology for storing propellent in space, which will be a component of a transportation infrastructure supported by in situ resource utilization such as ice mining on the moon for processing into rocket fuel. A key focus of the work by Eta Space will be standardization of equipment interfaces allowing multiple customers to tap into storage capability on orbit.

Eta Space’s LOXSAT 1 mission concept will test a range of cryogenic fuel management processes in space over 9 months specific to liquid oxygen management. LOX is a common oxidizer used across multiple propellant systems by several launch providers and is the heaviest cryogenic fluid needed by most customers.

Project RegoLight: Solar sintering lunar soil for 3D printed settlements on the Moon

RegoLight mobile printing head as implemented. Credits: RegoLight Consortium / Space Applications Services / International Astronautical Federation

Project RegoLight was an in situ resource utilization program funded by the European Commission to study automation of a process using solar energy to heat lunar soil to form building elements for a lunar settlement. The project ran from 2016 – 2018 and was intended to raise the technology readiness level from 3 to 5. The conclusions of the project were presented at the 69th International Astronautical Congress (IAC) held in Bremen, Germany in October 2018 and summarized in a report available on Academia.edu.

RegoLight had several primary objectives including automation of additive manufacturing of building elements under ambient conditions, fabrication of larger structures with a mobile printing head, demonstration of solar sintering under vacuum conditions, production of building elements using simulated lunar soil, material characterization of the building elements and other related processes in the context of a lunar settlement architecture. These activities would support plans for the Moon Village.

Conceptual view of an operational lunar base. Credits: RegoLight Consortium / LIQUIFER Systems Group / International Astronautical Federation

Rapid bootstrapping for faster ignition of off-Earth industry development

Artist’s concept of an O’Neill space colony. Credits: Blue Origin

In a thread on Twitter Philip Metzger, a planetary physicist at the University of Central Florida, updates his bootstrapping vision from a few years back in which he and colleagues at NASA published a paper on how robotics, 3D printing and in situ resource utilization could be leveraged to accelerate a solar system civilization. In a series of 9 Tweets, Metzger makes the case for his “Rapid Bootstrapping Scenario” as the preferred course out of three possible alternatives to get us there faster.

Many space enthusiasts, including Blue Origin CEO Jeff Bezos, advocate for what Metzger calls a solar system “Civilization Fully Revolutionized”. This is a future where most industrial manufacturing is done sustainably in space and Earth is preserved as a beautiful natural environment.

If we continue on the current path, down what Metzger calls “The Slow Growth Scenario”, space agencies like NASA will continue paving the technological highway for private entities to slowly develop their profitable enterprises. But because space exploration and development is difficult, a different approach is needed to prime the pump. Metzger suggests the preferred course of action is intentional pre-economic bootstrapping in which “…visionary individuals with means, citizen-led movements, or governments that see the long-term benefit of getting beyond our planetary limit…create a coalition of likeminded citizen movements and enlightened governments committed to a good future so we reach the ‘ignition’ point first by being fast”.

Source: Philip Metzger/UCF. @DrPhiltill. www.philipmetzger.com