Deimos (moon)

Deimos /ˈdməs/ (systematic designation: Mars II)[10] is the smaller and outermost of the two natural satellites of Mars, the other being Phobos. Of similar composition to C and D-type asteroids, Deimos has a mean radius of 6.2 km (3.9 mi) and takes 30.3 hours to orbit Mars.[5] Deimos is 23,460 km (14,580 mi) from Mars, much farther than Mars's other moon, Phobos.[11] It is named after Deimos, the Ancient Greek god and personification of dread and terror.

Deimos
An enhanced-color image of Deimos by Mars Reconnaissance Orbiter
Discovery
Discovered byAsaph Hall
Discovery date12 August 1877
Designations
Designation
Mars II
Pronunciation/ˈdməs/[1] to /ˈdməs/[2] or as Greek Δεῖμος (approximated /ˈdmɒs/)[3]
Named after
Δεῖμος
AdjectivesDeimian /ˈdmiən/[4]
Orbital characteristics
Epoch 23 September 2012 (JD 2456191.5)
Periapsis23455.5 km
Apoapsis23470.9 km
23463.2 km[5] (6.92 Mars radii)
Eccentricity0.00033[5]
1.263 d[5]
(30.312 h)
Average orbital speed
1.3513 km/s[6]
Inclination0.93° (to Mars's equator)
1.791° (to the local Laplace plane)[5]
27.58° (to the ecliptic)
Satellite ofMars
Physical characteristics
Dimensions15 km × 12.2 km × 11 km[7]
Mean radius
6.2±0.18 km[8]
(0.97316 mEarths)
Surface area
495.1548 km2
(0.970755 µEarths)
Volume999.78 km3
(0.922979 nEarths)
Mass1.4762×1015 kg[6]
(0.247179 nEarths)
Mean density
1.471±0.166 g/cm3[8]
Surface gravity
0.003 m/s2[6]
(306 µg)
5.556 m/s
(20 km/h)[6]
Synodic rotation period
Synchronous[5]
Albedo0.068±0.007[8]
Temperature233 K
12.89[9]

    Discovery and etymology

    Deimos was discovered by Asaph Hall III at the United States Naval Observatory in Washington, D.C. on 12 August 1877, at about 07:48 UTC.[lower-alpha 1] Hall, who also discovered Phobos shortly afterwards, had been specifically searching for Martian moons at the time.

    The moon is named after Deimos, a figure representing dread in Greek mythology.[10] The name was suggested by academic Henry Madan, who drew from Book XV of the Iliad, where Ares (the Roman god Mars) summons Dread (Deimos) and Fear (Phobos).[17]

    Origin

    The origin of Mars's moons is unknown and the hypotheses are controversial.[18] The main hypotheses are that they formed either by capture or by accretion. Because of the similarity to the composition of C- or D-type asteroids, one hypothesis is that the moons may be objects captured into Martian orbit from the asteroid belt, with orbits that have been circularized either by atmospheric drag or tidal forces,[19] as capture requires dissipation of energy. The current Martian atmosphere is too thin to capture a Phobos-sized object by atmospheric braking.[18] Geoffrey Landis has pointed out that the capture could have occurred if the original body was a binary asteroid that separated due to tidal forces.[20] The main alternative hypothesis is that the moons accreted in the present position. Another hypothesis is that Mars was once surrounded by many Phobos- and Deimos-sized bodies, perhaps ejected into orbit around it by a collision with a planetesimal.[21][22]

    Most recently, Amirhossein Bagheri (ETH Zurich), Amir Khan (ETH Zurich), Michael Efroimsky (US Naval Observatory) and their colleagues proposed a new hypothesis on the origin of the moons. By analyzing the seismic and orbital data from Mars InSight Mission and other missions, they proposed that the moons are born from disruption of a common parent body around 1 to 2.7 billion years ago. The common progenitor of Phobos and Deimos was most probably hit by another object and shattered to form Phobos and Deimos.[23]

    Physical characteristics

    Deimos, like Mars' other moon, Phobos, has spectra, albedos, and densities similar to those of a C- or D-type asteroid. Like most bodies of its size, Deimos is highly non-spherical with triaxial dimensions of 15 × 12.2 × 11 km,[7] making it 56% of the size of Phobos. Deimos is composed of rock rich in carbonaceous material, much like C-type asteroids and carbonaceous chondrite meteorites.[24] It is cratered, but the surface is noticeably smoother than that of Phobos, caused by the partial filling of craters with regolith. The regolith is highly porous and has a radar-estimated density of only 1.471 g/cm3.[25]

    Escape velocity from Deimos is 5.6 m/s.[6] This velocity could theoretically be achieved by a human performing a vertical jump.[26][27] The apparent magnitude of Deimos is 12.45.[8]

    Named geological features

    Only two geological features on Deimos have been given names. The craters Swift and Voltaire are named after writers who speculated on the existence of two Martian moons before Phobos and Deimos were discovered.[28]

    DEIMOS[29]
     VOLTAIRE 
     SWIFT 
    Deimos Crater Names (view • discuss)

    CratersCoordinatesDiameter
    (km)
    Approval
    Year
    EponymRef
    Swift12.5°N 1.8°E / 12.5; 1.8 (Swift)11973Jonathan Swift; Irish writer (1667–1745)WGPSN
    Voltaire22°N 3.5°W / 22; -3.5 (Voltaire)1.91973Voltaire; French writer (1694–1778)WGPSN

    Orbital characteristics

    Orbits of Phobos and Deimos (to scale)

    Deimos's orbit is nearly circular and is close to Mars's equatorial plane. Deimos is possibly an asteroid that was perturbed by Jupiter into an orbit that allowed it to be captured by Mars, though this hypothesis is still controversial and disputed.[18] Both Deimos and Phobos have very circular orbits which lie almost exactly in Mars' equatorial plane, and hence a capture origin requires a mechanism for circularizing the initially highly eccentric orbit, and adjusting its inclination into the equatorial plane, most likely by a combination of atmospheric drag and tidal forces;[19] it is not clear that sufficient time was available for this to have occurred for Deimos.[18]

    Curiosity's view of the Mars moons: Phobos passing in front of Deimos in real-time (video-gif, 1 August 2013)

    As seen from Mars, Deimos would have an angular diameter of no more than 2.5 minutes (sixty minutes make one degree), one twelfth of the width of the Moon as seen from Earth, and would therefore appear almost star-like to the naked eye.[30] At its brightest ("full moon") it would be about as bright as Venus is from Earth; at the first- or third-quarter phase it would be about as bright as Vega. With a small telescope, a Martian observer could see Deimos's phases, which take 1.2648[31] days (Deimos's synodic period) to run their course.[30]

    Unlike Phobos, which orbits so fast that it rises in the west and sets in the east, Deimos rises in the east and sets in the west. The Sun-synodic orbital period of Deimos of about 30.4 hours exceeds the Martian solar day ("sol") of about 24.7 hours by such a small amount that 2.48 days (2.41 sols) elapse between its rising and setting for an equatorial observer. From Deimos-rise to Deimos-rise (or setting to setting), 5.466 days (5.320 sols) elapse.

    Because Deimos's orbit is relatively close to Mars and has only a very small inclination to Mars's equator, it cannot be seen from Martian latitudes greater than 82.7°.

    Deimos's orbit is slowly getting larger, because it is far enough away from Mars and because of tidal acceleration. It is expected to eventually escape Mars's gravity.[32]

    Solar transits

    Deimos transits the Sun  as viewed by the Mars rover Opportunity (4 March 2004)

    Deimos regularly passes in front of the Sun as seen from Mars. It is too small to cause a total eclipse, appearing only as a small black dot moving across the Sun. Its angular diameter is only about 2.5 times the angular diameter of Venus during a transit of Venus from Earth. On 4 March 2004 a transit of Deimos was photographed by Mars rover Opportunity, and on 13 March 2004 a transit was photographed by Mars rover Spirit.

    Exploration

    Deimos and Phobos as seen from Mars, compared to the Moon as seen from Earth (in angular sizes)

    Overall, its exploration history is similar to those of Mars and of Phobos.[33] Deimos has been photographed in close-up by several spacecraft whose primary mission has been to photograph Mars. No landings on Deimos have been made.

    The Soviet Phobos program sent two probes to Phobos. In case Phobos 1 succeeded, Phobos 2 could have been sent to Deimos. Both probes launched successfully in July 1988. The first was lost en route to Mars, whereas the second returned some data and images but failed shortly before beginning its detailed examination of Phobos's surface, including a lander.

    In 1997 and 1998, the proposed Aladdin mission was selected as a finalist in the NASA Discovery Program. The plan was to visit both Phobos and Deimos, and launch projectiles at the satellites. The probe would collect the ejecta as it performed a slow flyby (~1 km/s).[34] These samples would be returned to Earth for study three years later.[35][36] The principal investigator was Carle M. Pieters of Brown University. The total mission cost, including launch vehicle and operations was $247.7 million.[37] Ultimately, the mission chosen to fly was MESSENGER, a probe to the planet Mercury.[38]

    In 2008, NASA Glenn Research Center began studying a Phobos and Deimos sample-return mission that would use solar electric propulsion. The study gave rise to the "Hall" mission concept, a New Frontiers-class mission currently under further study.[39]

    Also, the sample-return mission called Gulliver has been conceptualized and dedicated to Deimos,[40] in which 1 kilogram (2.2 pounds) of material from Deimos would be returned to Earth.[40]

    Another concept of sample-return mission from Phobos and Deimos is OSIRIS-REx 2, which would use heritage from the first OSIRIS-REx.[41]

    In March 2014, a Discovery class mission was proposed to place an orbiter on Mars orbit by 2021 and study Phobos and Deimos. It is called Phobos And Deimos & Mars Environment (PADME).[42][43]

    Human exploration of Deimos could serve as a catalyst for the human exploration of Mars. Recently, it was proposed that the sands of Deimos or Phobos could serve as a valuable material for aerobraking in the colonization of Mars.[44] See Phobos for more detail.

    See also

    Notes

    1. Given in contemporary sources as "11 August 14:40" Washington Mean Time, using a pre-1925 astronomical convention of beginning a day at noon,[12] so 12 hours must be added to get the actual local mean time.[13][14][15][16]

    References

    1. The Century Dictionary and Cyclopedia (1914)
    2. "Moons of Mars  the Center for Planetary Science".
    3. "Deimos". Lexico UK English Dictionary. Oxford University Press. Archived from the original on 22 March 2020.
    4. Harry Shipman (2013) Humans in Space: 21st Century Frontiers, p. 317
    5. "HORIZONS Web-Interface". NASA. 21 September 2013. Retrieved 4 December 2013.
    6. "Mars: Moons: Deimos". NASA Solar System Exploration. 30 September 2003. Archived from the original on 12 October 2012. Retrieved 2 December 2013.
    7. "Deimos". Retrieved 6 June 2014.
    8. "Planetary Satellite Physical Parameters". Jet Propulsion Laboratory (Solar System Dynamics). 13 July 2006. Retrieved 29 January 2008.
    9. "Mars' Moons".
    10. Blunck, Jürgen (2009). "The Satellites of Mars; Discovering and Naming the Satellites". Solar System Moons: Discovery and Mythology. Springer. p. 5. ISBN 978-3-540-68852-5.
    11. Staff (2016). "Deimos". SeaSky.org. Retrieved 23 January 2016.
    12. Campbell, W.W. (1918). "The Beginning of the Astronomical Day". Publications of the Astronomical Society of the Pacific. 30 (178): 358. Bibcode:1918PASP...30..358C. doi:10.1086/122784.
    13. Hall, A.; Observations of the Satellites of Mars, Astronomische Nachrichten, Vol. 91, No. 2161 (17 October 1877, signed 21 September 1877) pp. 11/12–13/14
    14. Morley, T. A.; A Catalogue of Ground-Based Astrometric Observations of the Martian Satellites, 1877–1982, Astronomy and Astrophysics Supplement Series, Vol. 77, No. 2 (February 1989), pp. 209–226 (Table II, p. 220: first observation of Deimos on 1877-08-12.32526)
    15. Notes: The Satellites of Mars, The Observatory, Vol. 1, No. 6 (20 September 1877), pp. 181–185
    16. The Discovery of the Satellites of Mars, Monthly Notices of the Royal Astronomical Society, Vol. 38, No. 4, (8 February 1878), pp. 205–209
    17. Hall, A.; Names of the Satellites of Mars, Astronomische Nachrichten, Vol. 92, No. 2187 (14 March 1878, signed 7 February 1878), p. 47/48
    18. Burns, J. A., "Contradictory Clues as to the Origin of the Martian Moons," in Mars, H. H. Kieffer et al., eds., U. Arizona Press, Tucson, 1992
    19. Cazenave, A.; Dobrovolskis, A.; Lago, B. (1980). "Orbital history of the Martian satellites with inferences on their origin". Icarus. 44 (3): 730–744. Bibcode:1980Icar...44..730C. doi:10.1016/0019-1035(80)90140-2.
    20. Landis, G. A., "Origin of Martian Moons from Binary Asteroid Dissociation," American Association for the Advancement of Science Annual Meeting; Boston, MA, 2001; abstract.
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    22. "Close Inspection for Phobos". accumulated ejecta from asteroid impacts on the Martian surface
    23. Bagheri, Amirhossein; Khan, Amir; Efroimsky, Michael; Kruglyakov, Mikhail; Giardini, Domenico (22 February 2021). "Dynamical evidence for Phobos and Deimos as remnants of a disrupted common progenitor". Nature Astronomy. 5 (6): 539–543. Bibcode:2021NatAs...5..539B. doi:10.1038/s41550-021-01306-2. ISSN 2397-3366. S2CID 233924981.
    24. "Moons of Mars – Planetary Sciences, Inc". Retrieved 10 June 2022.
    25. Busch, M. W.; et al. (2007). "Arecibo Radar Observations of Phobos and Deimos". Icarus. 186 (2): 581–584. Bibcode:2007Icar..186..581B. doi:10.1016/j.icarus.2006.11.003.
    26. "Vertical Jump Lab" (PDF).
    27. "Vertical Jump Velocity Estimation". Google Docs.
    28. "Gazetteer of Planetary Nomenclature". USGS Astrogeology Research Program.
    29. Lakdawalla, Emily (9 March 2009). "Mars Reconnaissance Orbiter eye candy: HiRISE images Deimos". Planetary Society. Retrieved 19 August 2013.
    30. Richardson, R. S. (December 1943), "If You Were on Mars", Astronomical Society of the Pacific Leaflets, vol. 4, Leaflet No. 178, pp. 214–221
    31. The Editors of Encyclopaedia Britannica. "Deimos". Encyclopedia Britannica. Retrieved 23 February 2019.
    32. "Deimos: Facts About the Smaller Martian Moon". Space.com.
    33. Mars Phobos and Deimos Survey (M-PADS)–A Martian Moons Orbiter and Phobos Lander (Ball, Andrew J.; Price, Michael E.; Walker, Roger J.; Dando, Glyn C.; Wells, Nigel S; and Zarnecki, John C. (2009). Mars Phobos and Deimos Survey (M-PADS)–A Martian Moons Orbiter and Phobos Lander. Advances in Space Research, 43(1), pp. 120–127.)
    34. Barnouin-Jha, Olivier S. (1999). "Aladdin: sample return from the moons of Mars". 1999 IEEE Aerospace Conference. Proceedings (Cat. No.99TH8403). Aerospace Conference, 1999. Proceedings. 1999 IEEE. Vol. 1. Aerospace Conference, 1999. Proceedings. 1999 IEEE. pp. 403–412 vol.1. doi:10.1109/AERO.1999.794346. ISBN 978-0-7803-5425-8. S2CID 129101577.
    35. Pieters, Carle. "ALADDIN: PHOBOS–DEIMOS SAMPLE RETURN" (PDF). 28th Annual Lunar and Planetary Science Conference. 28th Annual Lunar and Planetary Science Conference. Retrieved 28 March 2013.
    36. "Messenger and Aladdin Missions Selected as NASA Discovery Program Candidates". Retrieved 28 March 2013.
    37. "Five Discovery mission proposals selected for feasibility studies". Retrieved 28 March 2013.
    38. "NASA Selects Missions to Mercury and a Comet's Interior as Next Discovery Flights". Retrieved 28 March 2013.
    39. Lee, P. et al. 2010. Hall: A Phobos and Deimos Sample Return Mission. 44th Lunar Planet. Sci. Conf., The Woodlands, TX. 1–5 Mar 2010. [#1633] Bibcode:2010LPI....41.1633L.
    40. "Dr. Britt – The Gulliver Mission: Sample Return from Deimos" (PDF).
    41. Elifritz, T. L. (1 June 2012). "OSIRIS-REx II to Mars — Mars Sample Return from Phobos and Deimos". Concepts and Approaches for Mars Exploration. 1679: 4017. Bibcode:2012LPICo1679.4017E via NASA ADS.
    42. Lee, Pascal; Bicay, Michael; Colapre, Anthony; Elphic, Richard (17–21 March 2014). Phobos And Deimos & Mars Environment (PADME): A LADEE-Derived Mission to Explore Mars's Moons and the Martian Orbital Environment (PDF). 45th Lunar and Planetary Science Conference (2014).
    43. Reyes, Tim (1 October 2014). "Making the Case for a Mission to the Martian Moon Phobos". Universe Today. Retrieved 5 October 2014.
    44. Arias, Francisco. J (2017). On the Use of the Sands of Phobos and Deimos as a Braking Technique for Landing Large Payloads on Mars. 53rd AIAA/SAE/ASEE Joint Propulsion Conference Atlanta, GA, Propulsion and Energy, (AIAA 201–4876). doi:10.2514/6.2017-4876. ISBN 978-1-62410-511-1.
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