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Natural resources are abundant throughout the solar system, off Earth, but harvesting them is quite difficult and expensive.

Water for Propellent

Water has been discovered in the permanently shadowed polar craters of the Moon 1. This water can be melted and electrolyzed into hydrogen and oxygen, which can be used as rocket fuel 2. Several studies have examined the feasibility of doing this, relative to resupplying fuel from Earth.

Feasibility of Lunar Ice MiningStudies
FeasibleBlair et al. 3, Sowers 4, Sowers 5, Sowers and Dreyer 6
Feasible in optimum circumstancesBennett and Dempster 7, Jones et al. 8,9
InfeasibleDuke et al. 10, Jones et al. 11

In general, propellent from lunar ice is more likely to be economically feasible for geosynchronous satellites and deep space missions, and less so for low-Earth orbit satellites.

As of 2021, Masten Space Systems, Lunar Outpost, and Honeybee Robotics are working on lunar ice mining 12.

Water can also be recovered from near-Earth asteroids, from which water may be more abundant 13 and the economics of making fuel and propellant more favorable 1415. However, it should be remembered that asteroid mining remains challenging, with two recent prominent companies--Planetary Resources and Deep Space Industries--having failed 16.

Problem:
Emissions of Rocket Launch
Solution:
Strategic Propellant Reserve

Methane on Mars

The Sabatier process is a method of producing methane and water from carbon dioxide and hydrogen. The process is as follows.

The Sabatier process is an endothermic process, requires 165 kilojoules of heat for each mole of reaction. On Mars, the CO2-rich atmosphere is a source of carbon dioxide, while the water produced can be electrolyzed as a source of hydrogen. Source: Wikipedia.

The Sabatier process is of interest to allow fuel on a return rocket flight from Mars and is envisioned for a Mars sample return 17 or for SpaceX's Starship 18. The process is used currently on the International Space Station to recycle oxygen, but on Earth, it is not currently competitive with natural gas 19. Improving process catalysts is an active area of research 20.

Problem:
Emissions from natural gas
Solution:
Research and development into the Sabatier process

Asteroid Mining

There are several proposals to mine asteroids and other celestial bodies for raw materials, but nothing that will come to fruition soon.

Asteroid Mining Viability
MineralEconomic ViabilitySource
PlatinumYesHein et al.
Platinum-groupYesBusch
NickelNoLu
Helium-3NoKleinschneider et al.

Although asteroid mining has received considerable attention in the press, there are relatively few studies that analyze the economics rigorously. Above are results from some select analyses. Asteroid mining is likely to be economically viable only for high value minerals, such as platinum-group minerals 21. Sources: Busch 22, Hein et al. 21, Kleinschneider et al. 23, Lu 24.

Harvesting resources for use in space, such as water to make rocket fuel, is more likely to be economically viable than bringing resources back to Earth 25,21.

Launch costs would have to be below about $330 per kilogram to low-earth orbit (2020 dollars) 26 for asteroid mining to be economically viable, figures that SpaceX hopes to achieve with the under-development Starship. Near-earth asteroids, or those whose orbits come close to intersecting that of Earth, are most likely to be economical 27.

Solar Satellites

Space-based solar power (SBSP) is a proposed system that harvests solar energy from satellites in geosynchronous orbit. The satellites transit the power to a ground rectanna in the form of microwaves. While SPSP is probably technically possible 28, the economics are highly uncertain 29,30. Self-replicating factories on the Moon, which would launch components via a mass driver for arrangement in geosynchronous Earth orbit, have also been proposed 31.

Lacking reliable figures specifically for space-based solar, we take the cost of a full research program to be $65 billion, the same as the ITER project for fusion 32, and the time frame to be 40 years. We estimate the benefit to be about $9 billion, with an ultimately achievable cost of electricity of 7 ¢/kWh and otherwise the same greenhouse gas and other external costs of other forms of solar. See our research and development analysis for more details.

As the ultimate cost of SBSP is highly uncertain, and the appropriate discount rate is debatable, the benefit/cost ratio could vary widely.

Helium-3 Mining

Helium-3, a possible candidate for fusion fuel, accumulates on the lunar surface from solar wind. Mining this fuel and bringing it back to Earth would be an extensive operation, with several estimates of the feasibility of doing so.

FeasibilitySource
FeasibleSchmitt 33
Possibly FeasibleKleinschneider et al. 23
InfeasibleClose 34

For lunar helium-3 mining to be sensible, the following must hold:

  • fusion power is economical,
  • the deuterium-helium-3 route is superior to the deuterium-tritium or the proton-boron-11 routes, and
  • lunar mining is more economical than harvesting helium-3 as a decay product of tritium.

We see no reason to expect the second point, nor are we aware of a reliable analysis on the third.

The image: "moon_nuclear.svg" cannot be found!

Th, U, Pu, Li, T, D, and 3He are thorium, uranium, plutonium, lithium, tritium, deuterium, and helium-3 respectively. Lunar and imported deuterium indicated whether the D is to be harvested from the lunar surface or imported from Earth, where it is much more abundant. Source: 35.

The 163 million TWh of helium-3 available for D3He reactions would last 1400 years at present world energy demand 35. This assumes that the entire surface of the moon is strip-mined of helium-3 to three meters. If we assume that world energy demand grows by a factor of 5 for a civilization capable of such a mining operation, that only a fifth of lunar helium-3 is recoverable, and the overall efficiency (including heat losses in the power plant and the energy cost of strip mining and transportation) of the mining operation is 25%, then there are only 14 years of He3 reserves available.

It is also proposed to mine helium-3 from gas giants 36, including Uranus 37, though this is even more logistically difficult than mining the moon.

Aside from possible use for fusion, helium-3 is used as a neutron detector to screen for fissile materials. Fearing commercial shortage, the Department of Homeland Security has developed a detector using boron-10 instead of helium-3 and identifies the commercial supply of boron-10 to be sufficient 38. Helium-3 is also use for medical imaging of lungs 39 and for other purposes 40. Today, helium-3 is generated from the radioactive decay of tritium from nuclear reactors and nuclear weapons, and there is a commercial shortage mainly due to the post-September 11 spike in demand from security applications 40.

References

  1. Li, S., Lucey, P. G., Milliken, R. E., Hayne, P. O., Fisher, E., Williams, J., Hurley, D. M., Elphic, R. C. "Direct evidence of surface exposed water ice in the lunar polar regions". Proceedings of the National Academy of Sciences of the United States of America 115(36), pp. 8907-8912. September 2018.

  2. Kornuta, D. et al. "Commercial lunar propellant architecture: A collaborative study of lunar propellant production". REACH - Reviews in Human Space Exploration 13: 100026. March 2019.

  3. Blair, B. R., Diaz, J., Duke, M. B., Lamassoure, E., Easter, R., Oderman, M., Vaucher, M. "Space Resource Economic Analysis Toolkit: The Case for Commercial Lunar Ice Mining". Final Report to the NASA Exploration Team. December 2002.

  4. Sowers, G. F. "A cislunar transportation system fueled by lunar resources". Space Policy 37(2), pp. 103-109. August 2016.

  5. Sowers, G. F. "The Business Case for Lunar Ice Mining". New Space 9(2), pp. 77-94. June 2021.

  6. Sowers, G. F., Dreyer, C. B. "Ice Mining in Lunar Permanently Shadowed Regions". New Space 7(4), pp. 235-244. December 2019.

  7. Bennett, N. J., Dempster, A. G. "Geosynchronous transfer orbits as a market for impulse delivered by lunar sourced propellant". Planetary and Space Science 182: 104843. March 2020.

  8. Jones, C. A., Clark, M., Pensado, A., Ivanco, M. L., Reeves, D., Judd, E., Klovstad, J. "Cost Breakeven Analysis of Lunar ISRU for Human Lunar Surface Architectures". 70th International Astronautical Congress (IAC), Washington D.C., United States. October 2019.

  9. Jones, C. A., Pensado, A. R., Clark, M., Ivanco, M., Judd, E., Klovstad, J., Reeves, D. M. "Cost Breakeven Analysis of Lunar In-Situ Propellant Production for Human Missions to the Moon and Mars". ASCEND 2020, Session: Resource Extraction - Excavation/Material Acquisition. November 2020.

  10. Duke, M. B., Blair, B. R., Diaz, J. "Lunar resource utilization: Implications for commerce and exploration". Advances in Space Research 31(11), pp. 2413-2419. June 2003.

  11. Jones, C. A., Klovstad, J, J., Komar, D. R., Judd, E. L. "Cost Breakeven Analysis of Cis-lunar ISRU for Propellant". AIAA Scitech 2019 Forum, Session: In-Space Infrastructure. January 2019.

  12. Wall, M. "Space miners may use rockets to harvest the moon's water ice". space.com. July 2021.

  13. Rivkin, A. S., DeMeo, F. E. "How Many Hydrated NEOs Are There?". Journal of Geophysical Research: Planets 124(1), pp. 128-142. January 2019.

  14. Calla, P., Fries, D., Welch, C. "Asteroid mining with small spacecraft and its economic feasibility". arXiv. June 2019.

  15. Hein, A. M., Matheson, R., Fries, D. "A techno-economic analysis of asteroid mining". Acta Astronautica 168, pp. 104-115. March 2020.

  16. Abrahamiam, A. A. "How the asteroid-mining bubble burst". MIT Technology Review. June 2019.

  17. Green, S., Deffenbaugh, D., Miller, M. "A comparison of five ISPP systems for a Mars Sample Return Mission". 35th Joint Propulsion Conference and Exhibit, Los Angeles,CA, U.S.A. June 1999.

  18. Anzlowar, I. "Making Methane on Mars". University of California - Irvine. January 2021.

  19. Sheehan, S. W. "Electrochemical methane production from CO2 for orbital and interplanetary refueling". iScience 24(3): 102230. March 2021.

  20. Petersen, E. "Fueling the mission to Mars and Earth’s transition to renewable energy: Increasing catalyst performance for carbon dioxide methanation". Doctoral dissertation, Iowa State University. 2019.

  21. Hein, A. M., Matheson, R., Fries, D. "A techno-economic analysis of asteroid mining". Acta Astronautica 168, pp. 104-115. March 2020. 2 3

  22. Busch, M. "Profitable Asteroid Mining". Journal of the British Interplanetary Society, 57, pp. 301-305. 2004.

  23. Kleinschneider, A., Van Overstraeten, D., Van der Reijnst, R., Van Hoorn, N., Lamers, M., Hubert, L., Dijk, B., Blangé, J., Hogeveen, J., De Boer, L., Noomen, R. "Feasibility of lunar Helium-3 mining". 40th COSPAR Scientific Assembly. Held 2-10 August 2014, in Moscow, Russia, Abstract id. B0.1-58-14. August 2014. 2

  24. Lu, A. "Asteroid Mining Could Be The Next Frontier For Resource Mining". International Business Times. April 2015.

  25. Calla, P., Fries, D., Welch, C. "Asteroid mining with small spacecraft and its economic feasibility". arXiv preprint arXiv:1808.05099. April 2018.

  26. Sonter, M. J. "The technical and economic feasibility of mining the near-earth asteroids". University of Wollongong Thesis Collection, Department of Physics. 1996.

  27. Vergaaij, M., McInnes, C. R., Ceriotti, M. "Economic assessment of high-thrust and solar-sail propulsion for near-earth asteroid mining". Advances in Space Research 67(9). May 2021.

  28. National Security Space Office. "Space-Based Solar Power As an Opportunity for Strategic Security, Phase 0 Architecture Feasibility Study". October 2007.

  29. Jaffe, P. "A Modular Space Solar Power Pathfinder Mission in Low Earth Orbit". Accessed August 1, 2019.

  30. Mankins, J. "New Developments in Space Solar Power". National Space Society Space Settlement Journal. December 2017.

  31. Lewis-Weber, J. "Lunar-Based Self-Replicating Solar Factory". New Space 4(1), pp. 53-62. March 2016.

  32. Kramer, D. "ITER disputes DOE’s cost estimate of fusion project". Physics Today. April 2018.

  33. Schmitt, H. "Perspectives on Lunar Helium-3". Space Resources Utilization Roundtable, p. 33. January 1999.

  34. ZapperZ. "Fears Over Factoids". Physics and Physicists. August 2007.

  35. Bruhaug, G., Phillips, W. "Nuclear Fuel Resources of the Moon: A Broad Analysis of Future Lunar Nuclear Fuel Utilization". NSS Space Settlement Journal. June 2021. 2

  36. Jimodell. "Habitats can Extract Elements from the Gas Giant Region". A Though Experiment. September 2011.

  37. Gilster, P. "Starship Fuel from the Outer System". Centauri Dreams. June 2011.

  38. Slovik, G. "Alternatives for He-3". Department of Homeland Security, Domestic Nuclear Detection Office, Product Acquisition and Deployment Directorate. January 2012.

  39. Altes, T., Salerno, M. "Hyperpolarized Gas MR Imaging of the Lung". Journal of Thoracic Imaging 19(4), pp. 250-258. October 2004.

  40. McElroy, M. "AAAS Workshop Explores How to Meet Demand for Helium-3 in Medicine, Industry, and Security". American Association for the Advancement of Science. April 2013. 2