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433 Eros

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433 Eros
Eros – composite image of the north polar region, with the craters Psyche above and Himeros below. The long ridge Hinks Dorsum, believed to be a thrust fault, can be seen snaking diagonally between them. The smaller crater in the foreground is Narcissus. Watters, (2011)
Discovery [1]
Discovered byC. G. Witt
Discovery siteBerlin Urania Obs.
Discovery date13 August 1898
Designations
(433) Eros
Pronunciation/ˈɪərɒs/[2]
Named after
Ἔρως, Érōs[3]
  • 1898 DQ
  • 1956 PC
AdjectivesErotian /ɛˈrʃ(i)ən/[4]
Symbol (astrological)
Orbital characteristics[1]
Epoch 4 September 2017 (JD 2458000.5)
Uncertainty parameter 0
Observation arc53.89 yr (19,683 days)
Earliest precovery date29 October 1893
Aphelion1.7825 AU
Perihelion1.1334 AU
1.4579 AU
Eccentricity0.2226
1.76 yr (643 days)
71.280°
0° 33m 35.64s / day
Inclination10.828°
304.32°
178.82°
Earth MOID0.1505 AU (58.6 LD)
Mars MOID0.2407 AU
Physical characteristics
Dimensions
  • 16.84±0.06 km (mean diameter)[1][5]
  • 34.4 × 11.2 × 11.2 km[1][6]
Mass(6.687±0.003)×1015 kg[5]
Mean density
2.67±0.03 g/cm3[1][5]
5.270 h[1]
0.25±0.06[1]
7.0–15[7]
11.16[1]

433 Eros is a stony asteroid of the Amor group, and the first discovered, and second-largest near-Earth object. It has an elongated shape and a volume-equivalent diameter of approximately 16.8 kilometers (10.4 miles). Visited by the NEAR Shoemaker space probe in 1998, it became the first asteroid ever studied from its own orbit.

The asteroid was discovered by German astronomer C. G. Witt at the Berlin Observatory on 13 August 1898 in an eccentric orbit between Mars and Earth. It was later named after Eros, a god from Greek mythology, the son of Aphrodite. He is identified with the planet Venus.[3]

History

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Discovery

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Eros was discovered on 13 August 1898 by Carl Gustav Witt at Berlin Urania Observatory and Auguste Charlois at Nice Observatory.[8] Witt was taking a two-hour exposure of beta Aquarii to secure astrometric positions of asteroid 185 Eunike.[9]

Name

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Eros is named after the Greek god of love, Erōs. It was the first minor planet to be given a male name;[3] the break with earlier tradition was made because it was the first near-Earth asteroid discovered.

Later studies

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During the opposition of 1900–1901, a worldwide program was launched to make parallax measurements of Eros to determine the solar parallax (or distance to the Sun), with the results published in 1910 by Arthur Hinks of Cambridge[10] and Charles D. Perrine of the Lick Observatory, University of California.[11] Perrine published progress reports in 1906[12] and 1908.[13] He took 965 photographs with the Crossley Reflector and selected 525 for measurement.[14] A similar program was then carried out, during a closer approach, in 1930–1931 by Harold Spencer Jones.[15] The value of the Astronomical Unit (roughly the Earth-Sun distance) obtained by this program was considered definitive until 1968, when radar and dynamical parallax methods started producing more precise measurements.

Eros was the first asteroid detected by the Arecibo Observatory's radar system.[16][17]

Eros was one of the first asteroids visited by a spacecraft, the first one orbited, and the first one soft-landed on. NASA spacecraft NEAR Shoemaker entered orbit around Eros in 2000, and landed in 2001.

Mars-crosser

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Eros is a Mars-crosser asteroid, the first known to come within the orbit of Mars. Objects in such an orbit can remain there for only a few hundred million years before the orbit is perturbed by gravitational interactions. Dynamical system modeling suggests that Eros may evolve into an Earth-crosser within as short an interval as two million years, and has a roughly 50% chance of doing so over a time scale of 108~109 years.[18] It is a potential Earth impactor,[18] about five times larger than the impactor that created Chicxulub crater and led to the extinction of the non-avian dinosaurs.[a]

NEAR Shoemaker survey and landing

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The NEAR Shoemaker probe visited Eros twice, first with a brief flyby in 1998, and then by orbiting it in 2000, when it extensively photographed its surface. On 12 February 2001, at the end of its mission, it landed on the asteroid's surface using its maneuvering jets.

This was the first time a Near Earth asteroid was closely visited by a spacecraft.[19]

Physical characteristics

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Surface gravity depends on the distance from a spot on the surface to the center of a body's mass. Eros's surface gravity varies greatly because Eros is not a sphere but an elongated peanut-shaped object. The daytime temperature on Eros can reach about 100 °C (373 K) at perihelion. Nighttime measurements fall near −150 °C (123 K). Eros's density is 2.67 g/cm3, about the same as the density of Earth's crust.

NEAR scientists have found that most of the larger rocks strewn across Eros were ejected from a single crater in an impact approximately 1 billion years ago.[20] (The crater involved was proposed to be named "Shoemaker", but is not recognized as such by the International Astronomical Union (IAU), and has been formally designated Charlois Regio.) This event may also be responsible for the 40 percent of the Erotian surface that is devoid of craters smaller than 0.5 kilometers across. It was originally thought that the debris thrown up by the collision filled in the smaller craters. An analysis of crater densities over the surface indicates that the areas with lower crater density are within 9 kilometers of the impact point. Some of the lower density areas were found on the opposite side of the asteroid but still within 9 kilometers.[21]

It is thought that seismic shockwaves propagate through the asteroid, shaking smaller craters into rubble. Since Eros is irregularly shaped, parts of the surface antipodal to the point of impact can be within 9 kilometres of the impact point (measured in a straight line through the asteroid) even though some intervening parts of the surface are more than 9 kilometres away in straight-line distance. A suitable analogy would be the distance from the top centre of a bun to the bottom centre as compared to the distance from the top centre to a point on the bun's circumference: top-to-bottom is a longer distance than top-to-periphery when measured along the surface but shorter than it in direct straight-line terms.[21] Compression from the same impact is believed to have created the thrust fault Hinks Dorsum.[22]

A phenomenon named dust ponds were discovered in the asteroid in October 2000. Dust ponds are a phenomenon where pockets of dust are seen in airless celestial bodies. These are smooth deposits of dust accumulated in depressions on the surface of the body (like craters), contrasting from the rocky terrain around them. [23] They typically have different color and albedo compared to the surrounding areas. The asteroid contains lots of large craters more than 200 m in diameter. Their number is near to the saturation point of these craters. But craters smaller than that are relatively low. Suggesting that some process of erasure has covered them up. The floors of some craters are covered with smooth and flat areas (less than 10° slope). Such dust ponds are characterized by slightly bluer colour compared to the surrounding terrain. 334 of such ponds are identified, with a diameter of 10m. 255 of these are larger than 30m, and 231 (or 91%) are found within 30° from equator.

Data from the Near Earth Asteroid Rendezvous spacecraft collected on Eros in December 1998 suggests that it could contain 20 billion tonnes of aluminum and similar amounts of metals that are rare on Earth, such as gold and platinum.[24]

Visibility from Earth

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Path in sky during opposition 2011/2012

On 31 January 2012, Eros passed Earth at 0.17867 AU (26,729,000 km; 16,608,000 mi),[25][26] about 70 times the distance to the Moon, with a visual magnitude of +8.1.[27] During rare oppositions, every 81 years, such as in 1975 and 2056, Eros can reach a magnitude of +7.0,[7] which is brighter than Neptune and brighter than any main-belt asteroid except 1 Ceres, 4 Vesta and, rarely, 2 Pallas and 7 Iris. Under this condition, the asteroid actually appears to stop, but unlike the normal condition for a body in heliocentric conjunction with Earth, its retrograde motion is very small. For example, in January and February 2137, it moves retrograde only 34 minutes in right ascension.[1]

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In the novel and television series The Expanse, a catastrophic science experiment is unleashed on a civilian population living within tunnels cut through Eros. This so-called "Eros Incident" ends with the asteroid mysteriously breaking its usual orbit and crashing into Venus.[28]

It makes an appearance in the novel (and its film adaptation) Ender's Game by Orson Scott Card, serving as a base for humanity and the location of Command School after having been captured from the invading aliens (the Formics) prior to the initial novel who had used the asteroid as their forward operating base in their previous invasion.[29]

In the Space Angel episode 'Visitors from Outer Space' (title text not quite matching narration), Scott McCloud and his crew are forced to destroy Eros by deflecting it into the Sun, after it becomes a hazard to spacecraft navigation.[30]

It is the setting for the entirety of the plot of the novel Captive Universe by Harry Harrison.

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See also

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Notes

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  1. ^ Ratio of mean diameters is 16.84 km/~10 km; the volume ratio is approximately 4.8 (cubed value).

References

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  1. ^ a b c d e f g h i j k l m 433 Eros (1898 DQ). JPL Small-Body Database Browser (last obs.). Jet Propulsion Laboratory. 4 June 2017. Archived from the original on 11 July 2020. Retrieved 16 August 2017.
  2. ^ "Eros". Oxford English Dictionary (Online ed.). Oxford University Press. (Subscription or participating institution membership required.)
  3. ^ a b c Schmadel, Lutz D. (2007). "(433) Eros". Dictionary of Minor Planet Names. Springer Berlin Heidelberg. p. 50. doi:10.1007/978-3-540-29925-7_434. ISBN 978-3-540-00238-3.
  4. ^ John Amabile (2016) Changing the Worlds: The For-Profit Plan to Mine Asteroids and Terraform Two Planets in One Human Lifetime
  5. ^ a b c Yeomans, D.K.; Antreasian, P.G.; Barriot, J.-P.; Chesley, S.R.; Dunham, D.W.; Farquhar, R.W.; et al. (September 2000). "Radio science results during the NEAR-Shoemaker spacecraft rendezvous with Eros". Science. 289 (5487): 2085–2088. Bibcode:2000Sci...289.2085Y. doi:10.1126/science.289.5487.2085. ISSN 0036-8075. PMID 11000104.
  6. ^ Baer, Jim (2008). "Recent asteroid mass determinations". earthlink.net (personal website). Archived from the original on 29 January 2009. Retrieved 11 December 2008.
  7. ^ a b "NEODys (433) Eros ephemerides for 2137". Department of Mathematics. Pisa, Italy: University of Pisa. Archived from the original on 1 December 2022. Retrieved 27 June 2010.
  8. ^ Scholl, Hans; Schmadel, Lutz D. (2002). "Discovery circumstances of the first near-Earth asteroid (433) Eros". Acta Historica Astronomiae. 15: 210–220. Bibcode:2002AcHA...15..210S.
  9. ^ Yeomans, Donald K. (2014). Asteroid 433 Eros: The target body of the NEAR Mission (PDF). Jet Propulsion Laboratory (Report). California Institute of Technology. Archived from the original (PDF) on 28 September 2007.
  10. ^ Hinks, A.R. (1909). "Solar Parallax Papers no. 7: The general solution from the photographic right ascensions of Eros, at the opposition of 1900". Monthly Notices of the Royal Astronomical Society. 69 (7): 544–67. Bibcode:1909MNRAS..69..544H. doi:10.1093/mnras/69.7.544. Archived from the original on 26 July 2020. Retrieved 5 September 2019.
  11. ^ Perrine, Charles D. (1910). Determination of the solar parallax from photographs of Eros made with the Crossley reflector of the Lick Observatory, University of California (Report). Washington, DC: Carnegie Institution of Washington. pp. 1–104.
  12. ^ Perrine, C.D. (1906). "The measurement and reduction of the photographs of Eros made with the Crossley Reflector in 1900". Publications of the Astronomical Society of the Pacific. 18 (10): 226.
  13. ^ Perrine, Charles D. (1908). "Progress on the Crossley Eros solar parallax work". Publications of the Astronomical Society of the Pacific. 20 (120): 184. Bibcode:1908PASP...20..184P. doi:10.1086/121816. S2CID 121782316.
  14. ^ Campbell, W.W. (1906). "Reports of the observatories: Lick Observatory". Publications of the Astronomical Society of the Pacific. 19 (113): 92.
  15. ^ Jones, H.S. (1941). "The solar parallax and the mass of the Moon from observations of Eros at the opposition of 1931". Memoirs of the Royal Astronomical Society. 66: 11–66.
  16. ^ Butrica, Andrew J. (1996). To See the Unseen: A history of planetary radar astronomy (2nd ed.). Washington, DC: National Aeronautics and Space Administration. p. 224. ISBN 978-0160485787.
  17. ^ "Introduction to asteroid radar astronomy". Los Angeles, CA: University of California, Los Angeles. Archived from the original on 19 May 2014. Retrieved 19 May 2014.
  18. ^ a b Michel, Patrick; Farinella, Paolo; Froeschlé, Christiane (25 April 1996). "The orbital evolution of the asteroid Eros and implications for collision with the Earth". Nature. 380 (6576): 689–691. Bibcode:1996Natur.380..689M. doi:10.1038/380689a0. S2CID 4354612.
  19. ^ Svitil, Kathy A. (February 2001). "The end is near: The remarkable journey of a tough little space probe to the place where killer asteroids lurk". Discover Magazine. Archived from the original on 1 September 2020. Retrieved 30 September 2019 – via DiscoverMagazine.com.
  20. ^ Thomas, P.C.; Veverka, J.; Robinson, M.S.; Murchie, S. (27 September 2001). "Shoemaker crater as the source of most ejecta blocks on the asteroid 433 Eros". Nature. 413 (6854): 394–396. Bibcode:2001Natur.413..394T. doi:10.1038/35096513. ISSN 0028-0836. PMID 11574880. S2CID 4325299.
  21. ^ a b Thomas, P.C.; Robinson, M.S. (21 July 2005). "Seismic resurfacing by a single impact on the asteroid 433 Eros". Nature. 436 (7049): 366–369. Bibcode:2005Natur.436..366T. doi:10.1038/nature03855. PMID 16034412. S2CID 4425770.
  22. ^ Watters, T.R.; Thomas, P.C.; Robinson, M.S. (2011). "Thrust faults and the near-surface strength of asteroid 433 Eros". Geophysical Research Letters. 38 (2): L02202. Bibcode:2011GeoRL..38.2202W. doi:10.1029/2010GL045302. ISSN 0094-8276.
  23. ^ "Eros's puzzling surface". skyandtelescope.org. Archived from the original on 18 October 2023. Retrieved 18 October 2023.
  24. ^ "Gold rush in space?". BBC News. Archived from the original on 24 July 2020. Retrieved 13 December 2014.
  25. ^ 433 Eros (1898 DQ) (last obs). JPL Close-Approach Data. 13 November 2011. Archived from the original on 24 July 2020. Retrieved 14 November 2011.
  26. ^ "NEODyS-2 close approaches for (433) Eros". NEODyS-2 Near Earth Objects. European Space Agency / University of Pisa / Space Dynamics Service S.R.L. Archived from the original on 25 July 2020. Retrieved 14 November 2011.
  27. ^ "AstDys (433) Eros ephemerides for 2012". Department of Mathematics. Pisa, Italy: University of Pisa. Archived from the original on 25 July 2020. Retrieved 27 June 2010.
  28. ^ Scott Snowden (13 December 2019). "'The Expanse': Here's a Recap of Seasons 1-3 Ahead of Season 4 on Amazon Prime". Space. Archived from the original on 30 November 2022. Retrieved 18 December 2022.
  29. ^ Ender's Game and Philosophy: The Logic Gate is Down. John Wiley & Sons. 2013. p. 117.
  30. ^ "Space Angel VISITORS FROM OUTER SPACE". 2 December 2013. Archived from the original on 14 November 2022. Retrieved 18 December 2022 – via www.youtube.com.

Further reading

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  • Clark, C.S.; Clark, P.E. (13–17 March 2006). Using boundary-based mapping projections to reveal patterns in depositional and erosional features on 433 Eros. 37th Annual Lunar and Planetary Science Conference. League City, Texas. p. 1189. Bibcode:2006LPI....37.1189C. Abstract no.1189.
  • Riner, M. A.; et al. (November 2008). "Global survey of color variations on 433 Eros: Implications for regolith processes and asteroid environments". Icarus. 198 (1): 67–76. Bibcode:2008Icar..198...67R. doi:10.1016/j.icarus.2008.07.007.
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