List of tallest mountains in the Solar System

This is a list of the tallest mountains in the Solar System. The tallest peak or peaks on worlds where significant mountains have been measured are given. For some worlds, the tallest peaks of different classes are also listed. At 21.9 km (13.6 mi), the enormous shield volcano Olympus Mons on Mars is the tallest mountain on any planet in the Solar System. For 40 years, following its discovery in 1971, it was the tallest mountain known in the Solar System. However, in 2011, the central peak of the crater Rheasilvia on the asteroid and protoplanet Vesta was found to be of comparable height.[n 1] Due to limitations in the data and the definition problem described below, it is difficult to determine which of the two is taller.

Olympus Mons on Mars, the tallest planetary mountain in the Solar System, compared to Mount Everest and Mauna Kea on Earth (heights shown are above datum or sea level, which differ from the base-to-peak heights given below)

List

Heights are given from base to peak (although a precise definition for mean base level is lacking). Peak elevations above sea level are only available on Earth, and possibly Titan.[1] On other worlds, peak elevations above an equipotential surface or a reference ellipsoid could be used if enough data is available for the calculation, but this is often not the case.

World Tallest peak(s) Base-to-peak height % of radius[n 2] Origin Notes
Mercury Caloris Montes ≤ 3 km (1.9 mi)[2][3] 0.12 impact[4] Formed by the Caloris impact
Venus Skadi Mons (Maxwell Montes massif) 6.4 km (4.0 mi)[5] (11 km above mean) 0.11 tectonic[6] Has radar-bright slopes due to metallic Venus snow, possibly lead sulfide[7]
Maat Mons 4.9 km (3.0 mi) (approx.)[8] 0.081 volcanic[9] Highest volcano on Venus
Earth[n 3] Mauna Kea and Mauna Loa 10.2 km (6.3 mi)[11] 0.16 volcanic 4.2 km (2.6 mi) of this is above sea level
Haleakala 9.1 km (5.7 mi)[12] 0.14 volcanic Rises 3.1 km above sea level[12]
Pico del Teide 7.5 km (4.7 mi)[13] 0.12 volcanic Rises 3.7 km above sea level[13]
Denali 5.3 to 5.9 km (3.3 to 3.7 mi)[14] 0.093 tectonic Tallest mountain base-to-peak on land[15][n 4]
Mount Everest 3.6 to 4.6 km (2.2 to 2.9 mi)[16] 0.072 tectonic 4.6 km on north face, 3.6 km on south face;[n 5] highest elevation (8.8 km) above sea level (but not among the tallest from base to peak)
Moon[n 6] Mons Huygens 5.5 km (3.4 mi)[19][20] 0.32 impact Formed by the Imbrium impact
Mons Hadley 4.5 km (2.8 mi)[19][20] 0.26 impact Formed by the Imbrium impact
Mons Rümker 1.1 km (0.68 mi)[21] 0.063 volcanic Largest volcanic construct on the Moon[21]
Mars Olympus Mons 21.9 km (14 mi)[n 7][22][23] 0.65 volcanic Rises 26 km above northern plains,[24] 1000 km away. Summit calderas are 60 x 80 km wide, up to 3.2 km deep;[23] scarp around margin is up to 8 km high.[25] A shield volcano, the mean flank slope is a modest 5.2 degrees.[22]
Ascraeus Mons 14.9 km (9.3 mi)[22] 0.44 volcanic Tallest of the three Tharsis Montes
Elysium Mons 12.6 km (7.8 mi)[22] 0.37 volcanic Highest volcano in Elysium
Arsia Mons 11.7 km (7.3 mi)[22] 0.35 volcanic Summit caldera is 108 to 138 km (67 to 86 mi) across[22]
Pavonis Mons 8.4 km (5.2 mi)[22] 0.25 volcanic Summit caldera is 4.8 km (3.0 mi) deep[22]
Anseris Mons 6.2 km (3.9 mi)[26] 0.18 impact Among the highest nonvolcanic peaks on Mars, formed by the Hellas impact
Aeolis Mons ("Mount Sharp") 4.5 to 5.5 km (2.8 to 3.4 mi)[27][n 8] 0.16 deposition and erosion[n 9] Formed from deposits in Gale crater;[32] the MSL rover has been ascending it since November 2014.[33]
Vesta Rheasilvia central peak 22 km (14 mi)[n 10][34][35] 8.4 impact Almost 200 km (120 mi) wide. See also: List of largest craters in the Solar System
Ceres Ahuna Mons 4 km (2.5 mi)[36] 0.85 cryovolcanic[37] Isolated steep-sided dome in relatively smooth area; max. height of ~ 5 km on steepest side; roughly antipodal to largest impact basin on Ceres
Io Boösaule Montes "South"[38] 17.5 to 18.2 km (10.9 to 11.3 mi)[39] 1.0 tectonic Has a 15 km (9 mi) high scarp on its SE margin[40]
Ionian Mons east ridge 12.7 km (7.9 mi) (approx.)[40][41] 0.70 tectonic Has the form of a curved double ridge
Euboea Montes 10.3 to 13.4 km (6.4 to 8.3 mi)[42] 0.74 tectonic A NW flank landslide left a 25,000 km3 debris apron[43][n 11]
unnamed (245° W, 30° S) 2.5 km (1.6 mi) (approx.)[44][45] 0.14 volcanic One of the tallest of Io's many volcanoes, with an atypical conical form[45][n 12]
Mimas Herschel central peak 7 km (4 mi) (approx.)[47] 3.5 impact See also: List of largest craters in the Solar System
Dione Janiculum Dorsa 1.5 km (0.9 mi)[48] 0.27 tectonic[n 13] Surrounding crust depressed ca. 0.3 km.
Titan Mithrim Montes ≤ 3.3 km (2.1 mi)[51] 0.13 tectonic[51] May have formed due to global contraction[52]
Doom Mons 1.45 km (0.90 mi)[53] 0.056 cryovolcanic[53] Adjacent to Sotra Patera, a 1.7 km (1.1 mi) deep collapse feature[53]
Iapetus equatorial ridge 20 km (12 mi) (approx.)[54] 2.7 uncertain[n 14] Individual peaks have not been measured
Oberon unnamed ("limb mountain") 11 km (7 mi) (approx.)[47] 1.4 impact (?) A value of 6 km was given shortly after the Voyager 2 encounter[58]
Pluto Tenzing Montes, peak "T2" ~6.2 km (3.9 mi)[59] 0.52 tectonic[60] (?) Composed of water ice;[60] named after Tenzing Norgay[61]
Piccard Mons[n 15][62][63] ~5.5 km (3.4 mi)[59] 0.46 cryovolcanic (?) ~220 km across;[64] central depression is 11 km deep[59]
Wright Mons[n 15][62][63] ~4.7 km (2.9 mi)[59] 0.40 cryovolcanic (?) ~160 km across;[62] summit depression ~56 km across[65] and 4.5 km deep[59]
Charon Butler Mons[66] ≥ 4.5 km (2.8 mi)[66] 0.74 tectonic (?) Vulcan Planitia, the southern plains, has several isolated peaks, possibly tilted crustal blocks[66]
Dorothy central peak[66] ~4.0 km (2.5 mi)[66] 0.66 impact North polar impact basin Dorothy, Charon's largest, is ∼240 km across and 6 km deep[66]

The following images are shown in order of decreasing base-to-peak height.

See also

Notes

  1. Olympus Mons is a much broader peak; its diameter of ~600 km (370 mi) is similar to that of Vesta itself, and has been compared to the size of the U.S. state of Arizona.
  2. 100 × ratio of peak height to radius of the parent world
  3. On Earth, mountain heights are constrained by glaciation; peaks are usually limited to elevations not more than 1500 m above the snow line (which varies with latitude). Exceptions to this trend tend to be rapidly forming volcanoes.[10]
  4. On p. 20 of Helman (2005): "the base to peak rise of Mount McKinley is the largest of any mountain that lies entirely above sea level, some 18,000 ft (5,500 m)"
  5. Peak is 8.8 km (5.5 mi) above sea level, and over 13 km (8.1 mi) above the oceanic abyssal plain.
  6. Prominences in crater rims are not typically viewed as peaks and have not been listed here. A notable example is an (officially) unnamed massif on the rim of the farside crater Zeeman that rises about 4.0 km above adjacent parts of the rim and about 7.57 km above the crater floor.[17] The formation of the massif does not appear to be explainable simply on the basis of the impact event.[18]
  7. Due to limitations in the accuracy of the measurements and the lack of a precise definition of "base", it is difficult to say whether this peak or the central peak of Vesta's crater Rheasilvia is the tallest mountain in the Solar System.
  8. About 5.25 km (3.26 mi) high from the perspective of the landing site of Curiosity.[28]
  9. A crater central peak may sit below the mound of sediment. If that sediment was deposited while the crater was flooded, the crater may have once been entirely filled before erosional processes gained the upper hand.[27] However, if the deposition was due to katabatic winds that descend the crater walls, as suggested by reported 3 degree radial slopes of the mound's layers, the role of erosion would have been to place an upper limit on the mound's growth.[29][30] Gravity measurements by Curiosity suggest the crater was never buried by sediment, consistent with the latter scenario.[31]
  10. Due to limitations in the accuracy of the measurements and the lack of a precise definition of "base", it is difficult to say whether this peak or the volcano Olympus Mons on Mars is the tallest mountain in the Solar System.
  11. Among the Solar System's largest[43]
  12. Some of Io's paterae are surrounded by radial patterns of lava flows, indicating they are on a topographic high point, making them shield volcanoes. Most of these volcanoes exhibit relief of less than 1 km. A few have more relief; Ruwa Patera rises 2.5 to 3 km over its 300 km width. However, its slopes are only on the order of a degree.[46] A handful of Io's smaller shield volcanoes have steeper, conical profiles; the example listed is 60 km across and has slopes averaging 4° and reaching 6-7° approaching the small summit depression.[46]
  13. Was apparently formed via contraction.[49][50]
  14. Hypotheses of origin include crustal readjustment associated with a decrease in oblateness due to tidal locking,[55][56] and deposition of deorbiting material from a former ring around the moon.[57]
  15. Name not yet approved by the IAU
  16. A linearized wide-angle hazcam image that makes the mountain look steeper than it actually is. The highest peak is not visible in this view.

References

  1. Hayes, A.G.; Birch, S.P.D.; Dietrich, W.E.; Howard, A.D.; Kirk, R.L.; Poggiali, V.; Mastrogiuseppe, M.; Michaelides, R.J.; Corlies, P.M.; Moore, J.M.; Malaska, M.J.; Mitchell, K.L.; Lorenz, R.D.; Wood, C.A. (2017). "Topographic Constraints on the Evolution and Connectivity of Titan's Lacustrine Basins". Geophysical Research Letters. 44 (23): 11, 745–11, 753. doi:10.1002/2017GL075468.
  2. "Surface". MESSENGER web site. Johns Hopkins University/Applied Physics Lab. Archived from the original on 30 September 2016. Retrieved 4 April 2012.
  3. Oberst, J.; Preusker, F.; Phillips, R. J.; Watters, T. R.; Head, J. W.; Zuber, M. T.; Solomon, S. C. (2010). "The morphology of Mercury's Caloris basin as seen in MESSENGER stereo topographic models". Icarus. 209 (1): 230–238. Bibcode:2010Icar..209..230O. doi:10.1016/j.icarus.2010.03.009. ISSN 0019-1035.
  4. Fassett, C. I.; Head, J. W.; Blewett, D. T.; Chapman, C. R.; Dickson, J. L.; Murchie, S. L.; Solomon, S. C.; Watters, T. R. (2009). "Caloris impact basin: Exterior geomorphology, stratigraphy, morphometry, radial sculpture, and smooth plains deposits". Earth and Planetary Science Letters. 285 (3–4): 297–308. Bibcode:2009E&PSL.285..297F. doi:10.1016/j.epsl.2009.05.022. ISSN 0012-821X.
  5. Jones, Tom; Stofan, Ellen (2008). Planetology : Unlocking the secrets of the solar system. Washington, D.C.: National Geographic Society. p. 74. ISBN 978-1-4262-0121-9.
  6. Keep, M.; Hansen, V. L. (1994). "Structural history of Maxwell Montes, Venus: Implications for Venusian mountain belt formation". Journal of Geophysical Research. 99 (E12): 26015. Bibcode:1994JGR....9926015K. doi:10.1029/94JE02636. ISSN 0148-0227.
  7. Otten, Carolyn Jones (10 February 2004). "'Heavy metal' snow on Venus is lead sulfide". Newsroom. Washington University in Saint Louis. Retrieved 10 December 2012.
  8. "PIA00106: Venus - 3D Perspective View of Maat Mons". Planetary Photojournal. Jet Propulsion Lab. 1 August 1996. Retrieved 30 June 2012.
  9. Robinson, C. A.; Thornhill, G. D.; Parfitt, E. A. (January 1995). "Large-scale volcanic activity at Maat Mons: Can this explain fluctuations in atmospheric chemistry observed by Pioneer Venus?". Journal of Geophysical Research. 100 (E6): 11755–11764. Bibcode:1995JGR...10011755R. doi:10.1029/95JE00147. Retrieved 11 February 2013.
  10. Egholm, D. L.; Nielsen, S. B.; Pedersen, V. K.; Lesemann, J.-E. (2009). "Glacial effects limiting mountain height". Nature. 460 (7257): 884–887. Bibcode:2009Natur.460..884E. doi:10.1038/nature08263. PMID 19675651. S2CID 205217746.
  11. "Mountains: Highest Points on Earth". National Geographic Society. Retrieved 19 September 2010.
  12. "Haleakala National Park Geology Fieldnotes". U.S. National Park Service. Retrieved 31 January 2017.
  13. "Teide National Park". UNESCO World Heritage Site list. UNESCO. Retrieved 2 June 2013.
  14. "NOVA Online: Surviving Denali, The Mission". NOVA web site. Public Broadcasting Corporation. 2000. Retrieved 7 June 2007.
  15. Adam Helman (2005). The Finest Peaks: Prominence and Other Mountain Measures. Trafford Publishing. ISBN 978-1-4120-5995-4. Retrieved 9 December 2012.
  16. Mount Everest (1:50,000 scale map), prepared under the direction of Bradford Washburn for the Boston Museum of Science, the Swiss Foundation for Alpine Research, and the National Geographic Society, 1991, ISBN 3-85515-105-9
  17. Robinson, M. (20 November 2017). "Mountains of the Moon: Zeeman Mons". LROC.sese.asu. Arizona State University. Retrieved 5 September 2020.
  18. Ruefer, A.C.; James, P.B. (March 2020). "Zeeman Crater's Anomalous Massif" (PDF). 51st Lunar and Planetary Science Conference. p. 2673. Bibcode:2020LPI....51.2673R.
  19. Fred W. Price (1988). The Moon observer's handbook. London: Cambridge University Press. ISBN 978-0-521-33500-3.
  20. Moore, Patrick (2001). On the Moon. London: Cassell & Co.
  21. Wöhler, C.; Lena, R.; Pau, K. C. (16 March 2007), "The Lunar Dome Complex Mons Rümker: Morphometry, Rheology, and Mode of Emplacement", Lunar and Planetary Science Conference (1338): 1091, Bibcode:2007LPI....38.1091W
  22. Plescia, J. B. (2004). "Morphometric properties of Martian volcanoes". Journal of Geophysical Research. 109 (E3): E03003. Bibcode:2004JGRE..109.3003P. doi:10.1029/2002JE002031. ISSN 0148-0227.
  23. Carr, Michael H. (11 January 2007). The Surface of Mars. Cambridge University Press. p. 51. ISBN 978-1-139-46124-5.
  24. Comins, Neil F. (4 January 2012). Discovering the Essential Universe. Macmillan. ISBN 978-1-4292-5519-6. Retrieved 23 December 2012.
  25. Lopes, R.; Guest, J. E.; Hiller, K.; Neukum, G. (January 1982). "Further evidence for a mass movement origin of the Olympus Mons aureole". Journal of Geophysical Research. 87 (B12): 9917–9928. Bibcode:1982JGR....87.9917L. doi:10.1029/JB087iB12p09917.
  26. JMARS MOLA elevation dataset. Christensen, P.; Gorelick, N.; Anwar, S.; Dickenshied, S.; Edwards, C.; Engle, E. (2007) "New Insights About Mars From the Creation and Analysis of Mars Global Datasets;" American Geophysical Union, Fall Meeting, abstract #P11E-01.
  27. "Gale Crater's History Book". Mars Odyssey THEMIS web site. Arizona State University. Retrieved 7 December 2012.
  28. Anderson, R. B.; Bell III, J. F. (2010). "Geologic mapping and characterization of Gale Crater and implications for its potential as a Mars Science Laboratory landing site". International Journal of Mars Science and Exploration. 5: 76–128. Bibcode:2010IJMSE...5...76A. doi:10.1555/mars.2010.0004.
  29. Wall, M. (6 May 2013). "Bizarre Mars Mountain Possibly Built by Wind, Not Water". Space.com. Retrieved 13 May 2013.
  30. Kite, E. S.; Lewis, K. W.; Lamb, M. P.; Newman, C. E.; Richardson, M. I. (2013). "Growth and form of the mound in Gale Crater, Mars: Slope wind enhanced erosion and transport". Geology. 41 (5): 543–546. arXiv:1205.6840. Bibcode:2013Geo....41..543K. doi:10.1130/G33909.1. ISSN 0091-7613. S2CID 119249853.
  31. Lewis, K. W.; Peters, S.; Gonter, K.; Morrison, S.; Schmerr, N.; Vasavada, A. R.; Gabriel, T. (2019). "A surface gravity traverse on Mars indicates low bedrock density at Gale crater". Science. 363 (6426): 535–537. Bibcode:2019Sci...363..535L. doi:10.1126/science.aat0738. PMID 30705193. S2CID 59567599.
  32. Agle, D. C. (28 March 2012). "'Mount Sharp' On Mars Links Geology's Past and Future". NASA. Retrieved 31 March 2012.
  33. Webster, Gay; Brown, Dwayne (9 November 2014). "Curiosity Arrives at Mount Sharp". NASA Jet Propulsion Laboratory. Retrieved 16 October 2016.
  34. Vega, P. (11 October 2011). "New View of Vesta Mountain From NASA's Dawn Mission". Jet Propulsion Lab's Dawn mission web site. NASA. Archived from the original on 22 October 2011. Retrieved 29 March 2012.
  35. Schenk, P.; Marchi, S.; O'Brien, D. P.; Buczkowski, D.; Jaumann, R.; Yingst, A.; McCord, T.; Gaskell, R.; Roatsch, T.; Keller, H. E.; Raymond, C.A.; Russell, C. T. (1 March 2012), "Mega-Impacts into Planetary Bodies: Global Effects of the Giant Rheasilvia Impact Basin on Vesta", Lunar and Planetary Science Conference (1659): 2757, Bibcode:2012LPI....43.2757S, contribution 1659, id.2757
  36. "Dawn's First Year at Ceres: A Mountain Emerges". JPL Dawn website. Jet Propulsion Lab. 7 March 2016. Retrieved 8 March 2016.
  37. Ruesch, O.; Platz, T.; Schenk, P.; McFadden, L. A.; Castillo-Rogez, J. C.; Quick, L. C.; Byrne, S.; Preusker, F.; OBrien, D. P.; Schmedemann, N.; Williams, D. A.; Li, J.- Y.; Bland, M. T.; Hiesinger, H.; Kneissl, T.; Neesemann, A.; Schaefer, M.; Pasckert, J. H.; Schmidt, B. E.; Buczkowski, D. L.; Sykes, M. V.; Nathues, A.; Roatsch, T.; Hoffmann, M.; Raymond, C. A.; Russell, C. T. (2 September 2016). "Cryovolcanism on Ceres". Science. 353 (6303): aaf4286. Bibcode:2016Sci...353.4286R. doi:10.1126/science.aaf4286. PMID 27701087.
  38. Perry, Jason (27 January 2009). "Boösaule Montes". Gish Bar Times blog. Retrieved 30 June 2012.
  39. Schenk, P.; Hargitai, H. "Boösaule Montes". Io Mountain Database. Retrieved 30 June 2012.
  40. Schenk, P.; Hargitai, H.; Wilson, R.; McEwen, A.; Thomas, P. (2001). "The mountains of Io: Global and geological perspectives from Voyager and Galileo". Journal of Geophysical Research. 106 (E12): 33201. Bibcode:2001JGR...10633201S. doi:10.1029/2000JE001408. ISSN 0148-0227.
  41. Schenk, P.; Hargitai, H. "Ionian Mons". Io Mountain Database. Retrieved 30 June 2012.
  42. Schenk, P.; Hargitai, H. "Euboea Montes". Io Mountain Database. Retrieved 30 June 2012.
  43. Martel, L. M. V. (16 February 2011). "Big Mountain, Big Landslide on Jupiter's Moon, Io". NASA Solar System Exploration web site. Archived from the original on 13 January 2011. Retrieved 30 June 2012.
  44. Moore, J. M.; McEwen, A. S.; Albin, E. F.; Greeley, R. (1986). "Topographic evidence for shield volcanism on Io". Icarus. 67 (1): 181–183. Bibcode:1986Icar...67..181M. doi:10.1016/0019-1035(86)90183-1. ISSN 0019-1035.
  45. Schenk, P.; Hargitai, H. "Unnamed volcanic mountain". Io Mountain Database. Retrieved 6 December 2012.
  46. Schenk, P. M.; Wilson, R. R.; Davies, R. G. (2004). "Shield volcano topography and the rheology of lava flows on Io". Icarus. 169 (1): 98–110. Bibcode:2004Icar..169...98S. doi:10.1016/j.icarus.2004.01.015.
  47. Moore, Jeffrey M.; Schenk, Paul M.; Bruesch, Lindsey S.; Asphaug, Erik; McKinnon, William B. (October 2004). "Large impact features on middle-sized icy satellites" (PDF). Icarus. 171 (2): 421–443. Bibcode:2004Icar..171..421M. doi:10.1016/j.icarus.2004.05.009.
  48. Hammond, N. P.; Phillips, C. B.; Nimmo, F.; Kattenhorn, S. A. (March 2013). "Flexure on Dione: Investigating subsurface structure and thermal history". Icarus. 223 (1): 418–422. Bibcode:2013Icar..223..418H. doi:10.1016/j.icarus.2012.12.021.
  49. Beddingfield, C. B.; Emery, J. P.; Burr, D. M. (March 2013), "Testing for a Contractional Origin of Janiculum Dorsa on the Northern, Leading Hemisphere of Saturn's Moon Dione", Lunar and Planetary Science Conference (1719): 1301, Bibcode:2013LPI....44.1301B
  50. Overlooked Ocean Worlds Fill the Outer Solar System. John Wenz, Scientific American. 4 October 2017.
  51. "PIA20023: Radar View of Titan's Tallest Mountains". Photojournal.jpl.nasa.gov. Jet Propulsion Laboratory. 24 March 2016. Retrieved 25 March 2016.
  52. Mitri, G.; Bland,M. T.; Showman, A. P.; Radebaugh, J.; Stiles, B.; Lopes, R. M. C.; Lunine, J. I.; Pappalardo, R. T. (2010). "Mountains on Titan: Modeling and observations". Journal of Geophysical Research. 115 (E10002): E10002. Bibcode:2010JGRE..11510002M. doi:10.1029/2010JE003592. Retrieved 5 July 2012.
  53. Lopes, R. M. C.; Kirk, R. L.; Mitchell, K. L.; LeGall, A.; Barnes, J. W.; Hayes, A.; Kargel, J.; Wye, L.; Radebaugh, J.; Stofan, E. R.; Janssen, M. A.; Neish, C. D.; Wall, S. D.; Wood, C. A.; Lunine, J. I.; Malaska, M. J. (19 March 2013). "Cryovolcanism on Titan: New results from Cassini RADAR and VIMS" (PDF). Journal of Geophysical Research: Planets. 118 (3): 416. Bibcode:2013JGRE..118..416L. doi:10.1002/jgre.20062.
  54. Giese, B.; Denk, T.; Neukum, G.; Roatsch, T.; Helfenstein, P.; Thomas, P. C.; Turtle, E. P.; McEwen, A.; Porco, C. C. (2008). "The topography of Iapetus' leading side" (PDF). Icarus. 193 (2): 359–371. Bibcode:2008Icar..193..359G. doi:10.1016/j.icarus.2007.06.005. ISSN 0019-1035.
  55. Porco, C. C.; et al. (2005). "Cassini Imaging Science: Initial Results on Phoebe and Iapetus" (PDF). Science. 307 (5713): 1237–1242. Bibcode:2005Sci...307.1237P. doi:10.1126/science.1107981. ISSN 0036-8075. PMID 15731440. S2CID 20749556. 2005Sci...307.1237P.
  56. Kerr, Richard A. (6 January 2006). "How Saturn's Icy Moons Get a (Geologic) Life". Science. 311 (5757): 29. doi:10.1126/science.311.5757.29. PMID 16400121. S2CID 28074320.
  57. Ip, W.-H. (2006). "On a ring origin of the equatorial ridge of Iapetus" (PDF). Geophysical Research Letters. 33 (16): L16203. Bibcode:2006GeoRL..3316203I. doi:10.1029/2005GL025386. ISSN 0094-8276.
  58. Moore, P.; Henbest, N. (April 1986). "Uranus - the View from Voyager". Journal of the British Astronomical Association. 96 (3): 131–137. Bibcode:1986JBAA...96..131M.
  59. Schenk, P. M.; Beyer, R. A.; McKinnon, W. B.; Moore, J. M.; Spencer, J. R.; White, O. L.; Singer, K.; Nimmo, F.; Thomason, C.; Lauer, T. R.; Robbins, S.; Umurhan, O. M.; Grundy, W. M.; Stern, S. A.; Weaver, H. A.; Young, L. A.; Smith, K. E.; Olkin, C. (2018). "Basins, fractures and volcanoes: Global cartography and topography of Pluto from New Horizons". Icarus. 314: 400–433. Bibcode:2018Icar..314..400S. doi:10.1016/j.icarus.2018.06.008.
  60. Hand, E.; Kerr, R. (15 July 2015). "Pluto is alive—but where is the heat coming from?". Science. doi:10.1126/science.aac8860.
  61. Pokhrel, Rajan (19 July 2015). "Nepal's mountaineering fraternity happy over Pluto mountains named after Tenzing Norgay Sherpa - Nepal's First Landmark In The Solar System". The Himalayan Times. Retrieved 19 July 2015.
  62. "At Pluto, New Horizons Finds Geology of All Ages, Possible Ice Volcanoes, Insight into Planetary Origins". New Horizons News Center. The Johns Hopkins University Applied Physics Laboratory LLC. 9 November 2015. Retrieved 9 November 2015.
  63. Witze, A. (9 November 2015). "Icy volcanoes may dot Pluto's surface". Nature. doi:10.1038/nature.2015.18756. S2CID 182698872. Retrieved 9 November 2015.
  64. "Ice Volcanoes and Topography". New Horizons Multimedia. The Johns Hopkins University Applied Physics Laboratory LLC. 9 November 2015. Archived from the original on 13 November 2015. Retrieved 9 November 2015.
  65. "Ice Volcanoes on Pluto?". New Horizons Multimedia. The Johns Hopkins University Applied Physics Laboratory LLC. 9 November 2015. Archived from the original on 11 September 2017. Retrieved 9 November 2015.
  66. Schenk, P. M.; Beyer, R. A.; McKinnon, W. B.; Moore, J. M.; Spencer, J. R.; White, O. L.; Singer, K.; Umurhan, O. M.; Nimmo, F.; Lauer, T. R.; Grundy, W. M.; Robbins, S.; Stern, S. A.; Weaver, H. A.; Young, L. A.; Smith, K. E.; Olkin, C. (2018). "Breaking up is hard to do: Global cartography and topography of Pluto's mid-sized icy Moon Charon from New Horizons". Icarus. 315: 124–145. doi:10.1016/j.icarus.2018.06.010.
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