Colonization of the outer Solar System

Space colonization

Many parts of the outer Solar System have been considered for possible future colonization. Most of the larger moons of the outer planets contain water ice, liquid water, and organic compounds that might be useful for sustaining human life.[1][2]

Colonies in the outer Solar System could also serve as centers for long-term investigation of the planet and the other moons. In particular, robotic devices could be controlled by humans without the very long time delays incurred in communicating with Earth.

There have also been proposals to place robotic aerostats in the upper atmospheres of the Solar System's gas giant planets for exploration and possibly mining of helium-3, which could have a very high value per unit mass as a thermonuclear fuel.[3][4]

The Jovian System

Jovian radiation
Moonrem/day
Io3600[5]
Europa540[6]
Ganymede8[6]
Callisto0.01[6]

The Jovian system in general has particular disadvantages for colonization, including its severe radiation environment[7] and its particularly deep gravity well. Its radiation would deliver about 3,600 rems per day to unshielded colonists on Io and about 540 rems per day to unshielded colonists on Europa. Exposure to about 75 rems over a few days is enough to cause radiation poisoning, and about 500 rems over a few days is fatal.[8]

Jupiter itself, like the other gas giants, is not generally considered a good candidate for colonization.[9] There is no accessible surface on which to land, and the light hydrogen atmosphere would not provide good buoyancy for some kind of aerial habitat as has been proposed for Venus.

Io

Io is not ideal for colonization, due to its hostile environment. The moon is under influence of high tidal forces, causing high volcanic activity on the moon. Jupiter's strong radiation belt overshadows Io, delivering 3,600 rem a day to the moon. The moon is also extremely dry. Io is the least ideal place for colonization of the four Galilean moons. Despite this, its volcanoes could be energy resources for the other moons, better to colonize.

Europa

The magnetic field of Jupiter and corotation enforcing currents

The Artemis Project proposed a plan to colonize Europa.[10][11] Scientists would inhabit igloos and drill down into the Europan ice crust, exploring any subsurface ocean. The report also discusses use of air pockets for human habitation.

Ganymede

Ganymede is the largest moon in the Solar System. Ganymede is the only moon with a magnetosphere, but it is overshadowed by Jupiter's magnetic field. Ganymede receives about 8 rem of radiation per day.[6]

Callisto

Due to its distance from Jupiter's powerful radiation belt, Callisto is subject to only 0.01 rem a day.[6] When NASA carried out a study called HOPE (Revolutionary Concepts for Human Outer Planet Exploration) regarding the future exploration of the Solar System,[12] the target chosen was Callisto. It might be possible to build a surface base that would produce fuel for further exploration of the Solar System.

Jupiter trojans

The Keck Observatory announced in 2006 that the binary Jupiter trojan 617 Patroclus, and possibly many other Jupiter trojans, are likely composed of water ice, with a layer of dust. This suggests that mining water and other volatiles in this region and transporting them elsewhere in the Solar System, perhaps via the proposed Interplanetary Transport Network, may be feasible in the not-so-distant future. This could make colonization of the Moon, Mercury and main-belt asteroids more practical.

The Saturnian System

Robert Zubrin identified Saturn, Uranus and Neptune as "the Persian Gulf of the Solar System", as the largest sources of deuterium and helium-3 to drive a fusion economy, with Saturn the most important and most valuable of the three, because of its relative proximity, low radiation, and excellent system of moons.[13]

Titan

Zubrin identified Titan as possessing an abundance of all the elements necessary to support life, making Titan perhaps the most advantageous locale in the outer Solar System for colonization. He said, "In certain ways, Titan is the most hospitable extraterrestrial world within the Solar System for human colonization."[14] A widely published expert on terraforming, Christopher McKay, is also a co-investigator on the Huygens probe that landed on Titan in January 2005.

The surface of Titan is mostly uncratered and thus inferred to be very young and active, and probably composed of mostly water ice, and lakes of liquid hydrocarbons (methane/ethane) in its polar regions. While the temperature is cryogenic (95 K) it should be able to support a base, but more information regarding Titan's surface and the activities on it is necessary. The thick atmosphere and the weather, such as potential flash floods, are also factors to consider.

Enceladus

On March 9, 2006, NASA's Cassini space probe found possible evidence of liquid water on Enceladus.[15] According to that article, "pockets of liquid water may be no more than tens of meters below the surface." These findings were confirmed in 2014 by NASA. This means liquid water could be collected much more easily and safely on Enceladus than, for instance, on Europa (see above). Discovery of water, especially liquid water, generally makes a celestial body a much more likely candidate for colonization. An alternative model of Enceladus' activity is the decomposition of methane/water clathrates – a process requiring lower temperatures than liquid water eruptions. The higher density of Enceladus indicates a larger than Saturnian average silicate core that could provide materials for base operations.

Uranus

Because Uranus has the lowest escape velocity of the four gas giants, it has been proposed as a mining site for helium-3.[4] If human supervision of the robotic activity proved necessary, one of Uranus's natural satellites might serve as a base.

Neptune

It is hypothesized that one of Neptune's satellites could be used for colonization. Triton's surface shows signs of extensive geological activity that implies a subsurface ocean, perhaps composed of ammonia/water.[16] If technology advanced to the point that tapping such geothermal energy was possible, it could make colonizing a cryogenic world like Triton feasible, supplemented by nuclear fusion power.

Kuiper belt and Oort cloud

The noted physicist Freeman Dyson identified comets, rather than planets, as the major potential habitat of life in space.[17]

Difficulties

There would be many problems in colonizing the outer Solar System. These include:

  • Distance from Earth: The outer planets are much farther from Earth than the inner planets, and would therefore be harder and more time-consuming to reach. In addition, return voyages may well be prohibitive considering the time and distance.
  • Extreme cold: temperatures are near absolute zero in many parts of the outer Solar System.
  • Power: Solar power is many times less concentrated in the outer Solar System than in the inner Solar System. It is unclear as to whether it would be usable there, using some form of concentration mirrors, or whether nuclear power would be necessary. There have also been proposals to use the gravitational potential energy of planets or dwarf planets with moons.

See also

References

  1. G.J. Consalmagno, Ice-rich moons and the physical properties of ice,Journal of Physical Chemistry, vol. 87, no. 21, 1983, p. 4204-4208.
  2. Ralph Lorenz and Jacqueline Mitton, Lifting Titan's veil: exploring the giant moon of Saturn, Cambridge University Press, 2002
  3. Robert Zubrin, Entering Space: Creating a Spacefaring Civilization, section: Settling the Outer Solar System: The Sources of Power, pp. 158-160, Tarcher/Putnam, 1999, ISBN 1-58542-036-0
  4. 1 2 Jeffrey Van Cleve (Cornell University) et al., "Helium-3 Mining Aerostats in the Atmosphere of Uranus" Archived June 30, 2006, at the Wayback Machine., Abstract for Space Resources Roundtable, accessed May 10, 2006
  5. "Archived copy". Archived from the original on 2009-09-20. Retrieved 2009-09-20.
  6. 1 2 3 4 5 Frederick A. Ringwald (29 February 2000). "SPS 1020 (Introduction to Space Sciences)". California State University, Fresno. Archived from the original on 20 September 2009. Retrieved 2009-09-20.
  7. R. Walker Fillius, Carl E. McIlwain, and Antonio Mogro-Campero, Radiation Belts of Jupiter: A Second Look, Science, Vol. 188. no. 4187, pp. 465–467, 2 May 1975
  8. Robert Zubrin, Entering Space: Creating a Spacefaring Civilization, section: Colonizing the Jovian System, pp. 166-170, Tarcher/Putnam, 1999, ISBN 1-58542-036-0
  9. http://www.spacecolonization.xyz/colonization-of-jupiter/
  10. Artemis Society International official website
  11. Peter Kokh et al., "Europa II Workshop Report", Moon Miner's Manifesto #110, Nov. 1997
  12. Patrick A. Troutman (NASA Langley Research Center) et al., Revolutionary Concepts for Human Outer Planet Exploration (HOPE), accessed May 10, 2006 (.doc format)
  13. Robert Zubrin, Entering Space: Creating a Spacefaring Civilization, section: The Persian Gulf of the Solar System, pp. 161-163, Tarcher/Putnam, 1999, ISBN 1-58542-036-0
  14. Robert Zubrin, Entering Space: Creating a Spacefaring Civilization, section: Titan, pp. 163-166, Tarcher/Putnam, 1999, ISBN 1-58542-036-0
  15. "NASA's Cassini Discovers Potential Liquid Water on Enceladus". Nasa.gov. 2007-11-22. Retrieved 2011-08-20.
  16. Ruiz, Javier (2003). "Heat flow and depth to a possible internal ocean on Triton". Icarus. 166 (2): 436. Bibcode:2003Icar..166..436R. doi:10.1016/j.icarus.2003.09.009.
  17. Freeman Dyson, "The World, the Flesh, and the Devil", Third J.D. Bernal Lecture, May 1972, reprinted in Communication with Extraterrestrial Intelligence, Carl Sagan, ed., MIT Press, 1973, ISBN 0-262-69037-3

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