Habitability of natural satellites

The habitability of natural satellites describes the study of a moon's potential to provide habitats for life, though is not an indicator that it harbors it. Natural satellites are expected to outnumber planets by a large margin and the study is therefore important to astrobiology and the search for extraterrestrial life. There are, nevertheless, significant environmental variables specific to moons.

Europa, a potentially habitable moon of Jupiter

It is projected that parameters for surface habitats will be comparable to those of planets like Earth - stellar properties, orbit, planetary mass, atmosphere and geology. Of the natural satellites in the Solar System's habitable zone —the Moon, two Martian satellites (though some estimates put those outside it)[1] and numerous Minor-planet moons — all lack the conditions for surface water. Unlike the Earth, all planetary mass moons of the Solar System are tidally locked and it is not yet known to what extent this and tidal forces influence habitability.

Research suggests that deep biospheres like that of Earth are possible.[2] The strongest candidates therefore are currently icy satellites[3] such as those of Jupiter and SaturnEuropa[4] and Enceladus[5] respectively, in which subsurface liquid water is thought to exist. While the Lunar surface is hostile to life as we know it, a deep Lunar biosphere (or that of similar bodies) cannot yet be ruled out[6][7] deep exploration would be required for confirmation.

Exomoons are not yet confirmed to exist and their detection may be limited to transit-timing variation which is not currently sufficiently sensitive.[8] It is possible that some of their attributes could be found through study of their transits.[9] Despite this, some scientists estimate that there are as many habitable exomoons as habitable exoplanets.[10][11] Given the general planet-to-satellite(s) mass ratio of 10,000, gas giants in the habitable zone are thought to be the best candidates to harbour Earth-like moons.[12]

Tidal forces are likely to play as significant a role providing heat as stellar radiation.[13][14]

Presumed conditions

The conditions of habitability for natural satellites are similar to those of planetary habitability. However, there are several factors which differentiate natural satellite habitability and additionally extend their habitability outside the planetary habitable zone.[15]

Liquid water

Liquid water is thought by most astrobiologists to be an essential prerequisite for extraterrestrial life. There is growing evidence of subsurface liquid water on several moons in the Solar System orbiting the gas giants Jupiter, Saturn, Uranus, and Neptune. However, none of these subsurface bodies of water has been confirmed to date.

Orbital stability

For a stable orbit the ratio between the moon's orbital period Ps around its primary and that of the primary around its star Pp must be < 19, e.g. if a planet takes 90 days to orbit its star, the maximum stable orbit for a moon of that planet is less than 10 days.[16][17] Simulations suggest that a moon with an orbital period less than about 45 to 60 days will remain safely bound to a massive giant planet or brown dwarf that orbits 1 AU from a Sun-like star.[18]

Atmosphere

An atmosphere is considered by astrobiologists to be important in developing prebiotic chemistry, sustaining life and for surface water to exist. Most natural satellites in the Solar System lack significant atmospheres, the sole exception being Saturn's moon Titan.[19]

Sputtering, a process whereby atoms are ejected from a solid target material due to bombardment of the target by energetic particles, presents a significant problem for natural satellites. All the gas giants in the Solar System, and likely those orbiting other stars, have magnetospheres with radiation belts potent enough to completely erode an atmosphere of an Earth-like moon in just a few hundred million years. Strong stellar winds can also strip gas atoms from the top of an atmosphere causing them to be lost to space.

To support an Earth-like atmosphere for about 4.6 billion years (Earth's current age), a moon with a Mars-like density is estimated to need at least 7% of Earth's mass.[20] One way to decrease loss from sputtering is for the moon to have a strong magnetic field of its own that can deflect stellar wind and radiation belts. NASA's Galileo's measurements suggest that large moons can have magnetic fields; it found Ganymede has its own magnetosphere, even though its mass is only 2.5% of Earth's.[18] Alternatively, the moon's atmosphere may be constantly replenished by gases from subsurface sources, as thought by some scientists to be the case with Titan.[21]

Tidal effects

While the effects of tidal acceleration are relatively modest on planets, it can be a significant source of energy for natural satellites and an alternative energy source for sustaining life.

Moons orbiting gas giants or brown dwarfs are likely to be tidally locked to their primary: that is, their days are as long as their orbits. While tidal locking may adversely affect planets within habitable zones by interfering with the distribution of stellar radiation, it may work in favour of satellite habitability by allowing tidal heating. Scientists at the NASA Ames Research Center modelled the temperature on tide-locked exoplanets in the habitability zone of red dwarf stars. They found that an atmosphere with a carbon dioxide (CO
2
) pressure of only 1–1.5 standard atmospheres (15–22 psi) not only allows habitable temperatures, but allows liquid water on the dark side of the satellite. The temperature range of a moon that is tidally locked to a gas giant could be less extreme than with a planet locked to a star. Even though no studies have been done on the subject, modest amounts of CO
2
are speculated to make the temperature habitable.[18]

Tidal effects could also allow a moon to sustain plate tectonics, which would cause volcanic activity to regulate the moon's temperature[22][23] and create a geodynamo effect which would give the satellite a strong magnetic field.[24]

Axial tilt and climate

Provided gravitational interaction of a moon with other satellites can be neglected, moons tend to be tidally locked with their planets. In addition to the rotational locking mentioned above, there will also be a process termed 'tilt erosion', which has originally been coined for the tidal erosion of planetary obliquity against a planet's orbit around its host star.[25] The final spin state of a moon then consists of a rotational period equal to its orbital period around the planet and a rotational axis that is perpendicular to the orbital plane.

An exomoon with an earth-like atmosphere with liquid water filling its craters and water clouds. It orbits a jupiter like gas giant exoplanet in the habitable zone, mostly white due to water vapor clouds (Class II, in Sudarsky's exoplanet classification)

If the moon's mass is not too low compared to the planet, it may in turn stabilize the planet's axial tilt, i.e. its obliquity against the orbit around the star. On Earth, the Moon has played an important role in stabilizing the axial tilt of the Earth, thereby reducing the impact of gravitational perturbations from the other planets and ensuring only moderate climate variations throughout the planet.[26] On Mars, however, a planet without significant tidal effects from its relatively low-mass moons Phobos and Deimos, axial tilt can undergo extreme changes from 13° to 40° on timescales of 5 to 10 million years.[27][28]

Being tidally locked to a giant planet or sub-brown dwarf would allow for more moderate climates on a moon than there would be if the moon were a similar-sized planet orbiting in locked rotation in the habitable zone of the star.[29] This is especially true of red dwarf systems, where comparatively high gravitational forces and low luminosities leave the habitable zone in an area where tidal locking would occur. If tidally locked, one rotation about the axis may take a long time relative to a planet (for example, ignoring the slight axial tilt of Earth's moon and topographical shadowing, any given point on it has two weeks – in Earth time – of sunshine and two weeks of night in its lunar day) but these long periods of light and darkness are not as challenging for habitability as the eternal days and eternal nights on a planet tidally locked to its star.

Habitable edge

In 2012, scientists introduced a concept to define the habitable orbits of moons.[30] The concept is similar to the circumstellar habitable zone for planets orbiting a star, but for moons orbiting a planet. This inner border, which they call the circumplanetary habitable edge, delimits the region in which a moon can be habitable around its planet. Moons closer to their planet than the habitable edge are uninhabitable.

Magnetosphere

The magnetic environment of exomoons, which is critically triggered by the intrinsic magnetic field of the host planet, has been identified as another factor of exomoon habitability.[31] Most notably, it was found that moons at distances between about 5 and 20 planetary radii from a giant planet could be habitable from an illumination and tidal heating point of view,[31] but still the planetary magnetosphere would critically influence their habitability.[31]

Tidal-locking

Earth-sized exoplanets in the habitable zone around red dwarfs are often tidally locked to the host star. This has the effect that one hemisphere always faces the star, while the other remains in darkness. Like an exoplanet, an exomoon can potentially become tidally locked to its primary. However, since the exomoon's primary is an exoplanet, it would continue to rotate relative to its star after becoming tidally locked, and thus would still experience a day-night cycle indefinitely.

Scientists consider tidal heating as a threat for the habitability of exomoons.[32]

In the Solar System

The following is a list of natural satellites and environments in the Solar System with a possibility of hosting habitable environments:

NameSystemArticleNotes
EuropaJupiterColonization of EuropaThought to have a subsurface ocean maintained by geologic activity, tidal heating, and irradiation.[33][34] The moon may have more water and oxygen than Earth and an oxygen exosphere.[35]
EnceladusSaturnEnceladus – potential habitabilityThought to have a subsurface liquid water ocean due to tidal heating[36] or geothermal activity.[37] Free molecular hydrogen (H2) has been detected, providing another potential energy source for life.[38]
TitanSaturnColonization of TitanIts atmosphere is considered similar to that of the early Earth, although somewhat thicker. The surface is characterized by hydrocarbon lakes, cryovolcanos, and methane rain and snow. Like Earth, Titan is shielded from the solar wind by a magnetosphere, in this case its parent planet for most of its orbit, but the interaction with the moon's atmosphere remains sufficient to facilitate the creation of complex organic molecules. It has a remote possibility of an exotic methane-based biochemistry.[39]
CallistoJupiterCallisto – potential habitabilityThought to have a subsurface ocean heated by tidal forces.[40][41]
GanymedeJupiterGanymede – Subsurface oceansThought to have a magnetic field, with ice and subterranean oceans stacked up in several layers, with salty water as a second layer on top of the rocky iron core.[42][43]
IoJupiterDue to its proximity to Jupiter, it is subject to intense tidal heating which makes it the most volcanically active object in the Solar System. The outgassing generates a trace atmosphere.[44]
TritonNeptuneIts high orbital inclination with respect to Neptune's equator drives significant tidal heating,[45] which suggests a layer of liquid water or a subsurface ocean.[46]
DioneSaturnSimulations made in 2016 suggest an internal water ocean under 100 kilometres of crust possibly suitable for microbial life.[47]
CharonPlutoPossible internal ocean of water and ammonia, based on suspected cryovolcanic activity.[48]

Extrasolar

A total of 9 exomoon candidates have been detected, but none of them have been confirmed.

Given the general planet-to-satellite(s) mass ratio of 10,000, Large Saturn or Jupiter sized gas planets in the habitable zone are believed to be the best candidates to harbour Earth-like moons with more than 120 such planets by 2018.[12] Massive exoplanets known to be located within a habitable zone (such as Gliese 876 b, 55 Cancri f, Upsilon Andromedae d, 47 Ursae Majoris b, HD 28185 b and HD 37124 c) are of particular interest as they may potentially possess natural satellites with liquid water on the surface.

Artist's impression of a hypothetical moon around a Saturn-like exoplanet that could be habitable.

Habitability of extrasolar moons will depend on stellar and planetary illumination on moons as well as the effect of eclipses on their orbit-averaged surface illumination.[49] Beyond that, tidal heating might play a role for a moon's habitability. In 2012, scientists introduced a concept to define the habitable orbits of moons;[49] they define an inner border of an habitable moon around a certain planet and call it the circumplanetary "habitable edge". Moons closer to their planet than the habitable edge are uninhabitable. When effects of eclipses as well as constraints from a satellite's orbital stability are used to model the runaway greenhouse limit of hypothetical moons, it is estimated that — depending on a moon's orbital eccentricity — there is a minimum mass of roughly 0.20 solar masses for stars to host habitable moons within the stellar habitable zone.[17] The magnetic environment of exomoons, which is critically triggered by the intrinsic magnetic field of the host planet, has been identified as another factor of exomoon habitability.[31] Most notably, it was found that moons at distances between about 5 and 20 planetary radii from a giant planet could be habitable from an illumination and tidal heating point of view,[31] but still the planetary magnetosphere would critically influence their habitability.[31]

Natural satellites that host life are common in science fiction. Notable examples in film include: Earth's moon in A Trip to the Moon (1903); Yavin 4 from Star Wars (1977); Endor in Return of the Jedi (1983); Titan in Marvel Comics; LV-426 in Alien (1979) and Aliens (1986); Pandora from the Avatar franchise;[50] in the film Predators (2010); LV-223 in Prometheus (2012); Europa in Europa Report (2013) and Watchmen (2019); and K23 in The Midnight Sky (2020).

In the video game Kerbal Space Program and its sequel, there is a habitable satellite named Laythe.

In Halo the Kig-Yar homeworld, Eayn, orbits Chu'ot, the third planet in the Y'Deio system, which is located 41 light years from the Sol system.

In Mass Effect Andromeda the Angara homeworld, Harval, orbits the Gas Giant Faroang, which is also the namesake of their home system.

See also

References

  1. "Phoenix Mars Mission – Habitability and Biology". University of Arizona. 2014-04-24. Archived from the original on 2014-04-16.
  2. Boyd, Robert S. (8 March 2010). "Buried alive: Half of Earth's life may lie below land, sea". McClatchy DC. Archived from the original on 2014-04-25.
  3. Castillo, Julie; Vance, Steve (2008). "Session 13. The Deep Cold Biosphere? Interior Processes of Icy Satellites and Dwarf Planets". Astrobiology. 8 (2): 344–346. Bibcode:2008AsBio...8..344C. doi:10.1089/ast.2008.1237. ISSN 1531-1074.
  4. Greenberg, Richard (2011). "Exploration and Protection of Europa's Biosphere: Implications of Permeable Ice". Astrobiology. 11 (2): 183–191. Bibcode:2011AsBio..11..183G. doi:10.1089/ast.2011.0608. ISSN 1531-1074. PMID 21417946.
  5. Parkinson, Christopher D.; Liang, Mao-Chang; Yung, Yuk L.; Kirschivnk, Joseph L. (2008). "Habitability of Enceladus: Planetary Conditions for Life". Origins of Life and Evolution of Biospheres. 38 (4): 355–369. Bibcode:2008OLEB...38..355P. doi:10.1007/s11084-008-9135-4. ISSN 0169-6149. PMID 18566911. S2CID 15416810.
  6. Lingam, Manasvi; Loeb, Abraham (2020-09-21). "Potential for Liquid Water Biochemistry Deep under the Surfaces of the Moon, Mars, and beyond". The Astrophysical Journal. American Astronomical Society. 901 (1): L11. arXiv:2008.08709. doi:10.3847/2041-8213/abb608. ISSN 2041-8213.
  7. Crawford, Ian A; Cockell, Charles S (2010-07-23). "Astrobiology on the Moon". Astronomy & Geophysics. Oxford University Press (OUP). 51 (4): 4.11–4.14. doi:10.1111/j.1468-4004.2010.51411.x. ISSN 1366-8781.
  8. Kipping, David M.; Fossey, Stephen J.; Campanella, Giammarco (2009). "On the detectability of habitable exomoons withKepler-class photometry". Monthly Notices of the Royal Astronomical Society. 400 (1): 398–405. arXiv:0907.3909. Bibcode:2009MNRAS.400..398K. doi:10.1111/j.1365-2966.2009.15472.x. ISSN 0035-8711. S2CID 16106255.
  9. Kaltenegger, L. (2010). "Characterizing Habitable Exomoons". The Astrophysical Journal. 712 (2): L125–L130. arXiv:0912.3484. Bibcode:2010ApJ...712L.125K. doi:10.1088/2041-8205/712/2/L125. ISSN 2041-8205. S2CID 117385339.
  10. Shriber, Michael (26 Oct 2009). "Detecting Life-Friendly Moons". Astrobiology Magazine. Archived from the original on 2021-03-09. Retrieved 9 May 2013.{{cite web}}: CS1 maint: unfit URL (link)
  11. "Exomoons Could Be As Likely To Host Life As Exoplanets, Claims Scientists". Cosmos Up. 21 May 2018. Retrieved 27 May 2018.
  12. Jorgenson, Amber (5 June 2018). "Kepler data reveals 121 gas giants that could harbor habitable moons". Astronomy.
  13. Cowen, Ron (2008-06-07). "A Shifty Moon". Science News.
  14. Bryner, Jeanna (24 June 2009). "Ocean Hidden Inside Saturn's Moon". Space.com. TechMediaNetwork. Retrieved 22 April 2013.
  15. Scharf, Caleb A. (4 October 2011). "Exomoons Ever Closer". Scientific American.
  16. Kipping, David (2009). "Transit timing effects due to an exomoon". Monthly Notices of the Royal Astronomical Society. 392 (1): 181–189. arXiv:0810.2243. Bibcode:2009MNRAS.392..181K. doi:10.1111/j.1365-2966.2008.13999.x. S2CID 14754293.
  17. Heller, R. (2012). "Exomoon habitability constrained by energy flux and orbital stability". Astronomy & Astrophysics. 545: L8. arXiv:1209.0050. Bibcode:2012A&A...545L...8H. doi:10.1051/0004-6361/201220003. ISSN 0004-6361. S2CID 118458061.
  18. LePage, Andrew J. (August 1, 2006). "Habitable Moons". Sky & Telescope.
  19. Kuiper, Gerard P. (1944). "Titan: A satellite with an atmosphere". The Astrophysical Journal. 100: 378–383. Bibcode:1944ApJ...100..378K. doi:10.1086/144679.
  20. "In Search Of Habitable Moons". Pennsylvania State University. Retrieved 2011-07-11.
  21. Tobie, Gabriel; Lunine, Jonathan I. (2006). "Episodic outgassing as the origin of atmospheric methane on Titan". Nature. 440 (7080): 61–64. Bibcode:2006Natur.440...61T. doi:10.1038/nature04497. PMID 16511489. S2CID 4335141.
  22. Glatzmaier, Gary A. "How Volcanoes Work – Volcano Climate Effects". Retrieved 29 February 2012.
  23. "Solar System Exploration: Io". Solar System Exploration. NASA. Archived from the original on 16 December 2003. Retrieved 29 February 2012.
  24. Nave, R. "Magnetic Field of the Earth". Retrieved 29 February 2012.
  25. Heller, René; Barnes, Rory; Leconte, Jérémy (April 2011). "Tidal obliquity evolution of potentially habitable planets". Astronomy and Astrophysics. 528: A27. arXiv:1101.2156. Bibcode:2011A&A...528A..27H. doi:10.1051/0004-6361/201015809. S2CID 118784209.
  26. Henney, Paul. "How Earth and the Moon interact". Astronomy Today. Retrieved 25 December 2011.
  27. "Mars 101 – Overview". Mars 101. NASA. Retrieved 25 December 2011.
  28. Armstrong, John C.; Leovy, Conway B.; Quinn, Thomas (October 2004). "A 1 Gyr climate model for Mars: new orbital statistics and the importance of seasonally resolved polar processes". Icarus. 171 (2): 255–271. Bibcode:2004Icar..171..255A. doi:10.1016/j.icarus.2004.05.007.
  29. Choi, Charles Q. (27 December 2009). "Moons Like Avatar's Pandora Could Be Found". Space.com. Retrieved 16 January 2012.
  30. Heller, René; Rory Barnes (2012). "Exomoon habitability constrained by illumination and tidal heating". Astrobiology. 13 (1): 18–46. arXiv:1209.5323. Bibcode:2013AsBio..13...18H. doi:10.1089/ast.2012.0859. PMC 3549631. PMID 23305357.
  31. Heller, René (September 2013). "Magnetic shielding of exomoons beyond the circumplanetary habitable edge". The Astrophysical Journal Letters. 776 (2): L33. arXiv:1309.0811. Bibcode:2013ApJ...776L..33H. doi:10.1088/2041-8205/776/2/L33. S2CID 118695568.
  32. Heller, René; Rory Barnes (January 2013). "Exomoon habitability constrained by illumination and tidal heating". Astrobiology. 13 (1): 18–46. arXiv:1209.5323. Bibcode:2013AsBio..13...18H. doi:10.1089/ast.2012.0859. PMC 3549631. PMID 23305357.
  33. Greenberg, R.; Hoppa, G. V.; Tufts, B. R.; Geissler, P.; Riley, J.; Kadel, S. (October 1999). "Chaos on Europa". Icarus. 141 (2): 263–286. Bibcode:1999Icar..141..263G. doi:10.1006/icar.1999.6187.
  34. Schmidt, B. E.; Blankenship, D. D.; Patterson, G. W. (November 2011). "Active formation of 'chaos terrain' over shallow subsurface water on Europa". Nature. 479 (7374): 502–505. Bibcode:2011Natur.479..502S. doi:10.1038/nature10608. PMID 22089135. S2CID 4405195.
  35. "Moon of Jupiter could support life: Europa has a liquid ocean that lies beneath several miles of ice". NBC News. 2009-10-08. Retrieved 2011-07-10.
  36. Roberts, J. H.; Nimmo, Francis (2008). "Tidal heating and the long-term stability of a subsurface ocean on Enceladus". Icarus. 194 (2): 675–689. Bibcode:2008Icar..194..675R. doi:10.1016/j.icarus.2007.11.010.
  37. Boyle, Alan (March 9, 2006). "Liquid water on Saturn moon could support life: Cassini spacecraft sees signs of geysers on icy Enceladus". NBC News. Retrieved 2011-07-10.
  38. Nield, David (13 April 2017). "NASA: Saturn's Moon Enceladus Has All The Basic Ingredients For Life". sciencealert.com.
  39. "Colonization Of Titan? New Clues to What's Consuming Hydrogen, Acetylene On Saturn's Moon". Science Daily. 2010-06-07. Retrieved 2011-07-10.
  40. Phillips, T. (1998-10-23). "Callisto makes a big splash". Science@NASA. Archived from the original on 2009-12-29.
  41. Lipps, Jere H; Delory, Gregory; Pitman, Joe; et al. (2004). Hoover, Richard B; Levin, Gilbert V; Rozanov, Alexei Y (eds.). "Astrobiology of Jupiter's Icy Moons" (PDF). Proc. SPIE. Instruments, Methods, and Missions for Astrobiology VIII. 5555: 10. Bibcode:2004SPIE.5555...78L. doi:10.1117/12.560356. S2CID 140590649. Archived from the original (PDF) on 2008-08-20.
  42. "Ganymede May Harbor 'Club Sandwich' of Oceans and Ice". JPL@NASA. 2014-05-04.
  43. Vance, Steve; et al. (2014). "Astrobiology of Jupiter's Icy Moons". Planetary and Space Science. Instruments, Methods, and Missions for Astrobiology VIII. 96: 62. Bibcode:2014P&SS...96...62V. doi:10.1016/j.pss.2014.03.011.
  44. Charles Q. Choi (2010-06-07). "Chance For Life On Io". Science Daily. Retrieved 2011-07-10.
  45. Nimmo, Francis (15 January 2015). "Powering Triton's recent geological activity by obliquity tides: Implications for Pluto geology". Icarus. 246: 2–10. Bibcode:2015Icar..246....2N. doi:10.1016/j.icarus.2014.01.044. S2CID 40342189.
  46. Louis Neal Irwin; Dirk Schulze-Makuch (June 2001). "Assessing the Plausibility of Life on Other Worlds". Astrobiology. 1 (2): 143–60. Bibcode:2001AsBio...1..143I. doi:10.1089/153110701753198918. PMID 12467118.
  47. Mikael Beuthe, Attilio Rivoldini, Antony Trinh (2016-09-28). "Enceladus's and Dione's floating ice shells supported by minimum stress isostasy". Geophysical Research Letters. 43 (19): 10, 088–10, 096. arXiv:1610.00548. Bibcode:2016GeoRL..4310088B. doi:10.1002/2016GL070650. S2CID 119236092. Retrieved 2022-09-07.{{cite journal}}: CS1 maint: multiple names: authors list (link)
  48. Cook, Jason C.; Desch, Steven J.; Roush, Ted L.; Trujillo, Chadwick A.; Geballe, T.R. (2007). "Near-infrared spectroscopy of Charon: Possible evidence for cryovolcanism on Kuiper Belt objects". The Astrophysical Journal. 663 (2): 1406–1419. Bibcode:2007ApJ...663.1406C. doi:10.1086/518222. S2CID 122757071.
  49. Heller, René; Rory Barnes (2012). "Exomoon habitability constrained by illumination and tidal heating". Astrobiology. 13 (1): 18–46. arXiv:1209.5323. Bibcode:2013AsBio..13...18H. doi:10.1089/ast.2012.0859. PMC 3549631. PMID 23305357.
  50. McKie, Robin (13 January 2013). "Is there life on moons?". The Guardian. Retrieved 15 January 2017.
This article is issued from Wikipedia. The text is licensed under Creative Commons - Attribution - Sharealike. Additional terms may apply for the media files.