Vulcanoid

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The zone, represented by the orange region, in which vulcanoids may exist, compared with the orbits of Mercury, Venus and Earth Vulcanoidorbits.svg
The zone, represented by the orange region, in which vulcanoids may exist, compared with the orbits of Mercury, Venus and Earth

The vulcanoids are a hypothetical population of asteroids that orbit the Sun in a dynamically stable zone inside the orbit of the planet Mercury. They are named after the hypothetical planet Vulcan, which was proposed on the basis of irregularities in Mercury's orbit that were later found to be explained by general relativity. So far, no vulcanoids have been discovered, and it is not yet clear whether any exist.

Contents

If they do exist, the vulcanoids could easily evade detection because they would be very small and near the bright glare of the Sun. Due to their proximity to the Sun, searches from the ground can only be carried out during twilight or solar eclipses. Any vulcanoids must be between about 100 metres (330 ft) and 6 kilometres (3.7 mi) in diameter and are probably located in nearly circular orbits near the outer edge of the gravitationally stable zone between the Sun and Mercury. These should be distinguished from Atira asteroids, which may have perihelia within the orbit of Mercury, but whose aphelia extends as far as the orbits of Venus or within Earth's orbital path. Because they cross the orbit of Mercury, these bodies are not classed as vulcanoids.

The vulcanoids, should they be found, may provide scientists with material from the first period of planet formation, as well as insights into the conditions prevalent in the early Solar System. Although every other gravitationally stable region in the Solar System has been found to contain objects, non-gravitational forces (such as the Yarkovsky effect) or the influence of a migrating planet in the early stages of the Solar System's development may have depleted this area of any asteroids that may have been there.

History and observation

Celestial bodies interior to the orbit of Mercury have been hypothesized, and searched for, for centuries. The German astronomer Christoph Scheiner thought he had seen small bodies passing in front of the Sun in 1611, but these were later shown to be sunspots. [1] In the 1850s, Urbain Le Verrier made detailed calculations of Mercury's orbit and found a small discrepancy in the planet's perihelion precession from predicted values. He postulated that the gravitational influence of a small planet or ring of asteroids within the orbit of Mercury would explain the deviation. Shortly afterward, an amateur astronomer named Edmond Lescarbault claimed to have seen Le Verrier's proposed planet transit the Sun. The new planet was quickly named Vulcan but was never seen again, and the anomalous behaviour of Mercury's orbit was explained by Einstein's general theory of relativity in 1915. The vulcanoids take their name from this hypothetical planet. [2] What Lescarbault saw was probably another sunspot. [3]

Total solar eclipses provide an opportunity to search for vulcanoids from the ground. Zatm lagan.jpg
Total solar eclipses provide an opportunity to search for vulcanoids from the ground.

Vulcanoids, should they exist, would be difficult to detect due to the strong glare of the nearby Sun, [4] and ground-based searches can only be carried out during twilight or during solar eclipses. [5] Several searches during eclipses were conducted in the early 1900s, [6] which did not reveal any vulcanoids, and observations during eclipses remain a common search method. [7] Conventional telescopes cannot be used to search for them because the nearby Sun could damage their optics. [8]

In 1998, astronomers analysed data from the SOHO spacecraft's LASCO instrument, which is a set of three coronagraphs. The data taken between January and May of that year did not show any vulcanoids brighter than magnitude 7. This corresponds to a diameter of about 60 kilometres (37 mi), assuming the asteroids have an albedo similar to that of Mercury. In particular, a large planetoid at a distance of 0.18 AU, predicted by the theory of scale relativity, was ruled out. [9]

Later attempts to detect the vulcanoids involved taking astronomical equipment above the interference of Earth's atmosphere, to heights where the twilight sky is darker and clearer than on the ground. [10] In 2000, planetary scientist Alan Stern performed surveys of the vulcanoid zone using a Lockheed U-2 spy plane. The flights were conducted at a height of 21,300 metres (69,900 ft) during twilight. [11] In 2002, he and Dan Durda performed similar observations on an F-18 fighter jet. They made three flights over the Mojave Desert at an altitude of 15,000 metres (49,000 ft) and made observations with the Southwest Universal Imaging SystemAirborne (SWUIS-A). [12]

Even at these heights the atmosphere is still present and can interfere with searches for vulcanoids. In 2004, a sub-orbital spaceflight was attempted in order to get a camera above Earth's atmosphere. A Black Brant rocket was launched from White Sands, New Mexico, on January 16, carrying a powerful camera named VulCam, [13] on a ten-minute flight. [4] This flight reached an altitude of 274,000 metres (899,000 ft) [13] and took over 50,000 images. None of the images revealed any vulcanoids, but there were technical problems. [4]

Searches of NASA's two STEREO spacecraft data have failed to detect any vulcanoid asteroids. [14] It is doubtful that there are any vulcanoids larger than 5.7 kilometres (3.5 mi) in diameter. [14]

The MESSENGER space probe took a few images of the outer regions of the vulcanoid zone; however, its opportunities were limited because its instruments had to be pointed away from the Sun at all times to avoid damage. [15] [16] Before its demise in 2015, however, the craft failed to produce substantial evidence on vulcanoids.

On August 13, 2021, an asteroid, 2021 PH27 , was discovered with a perihelion well within the orbit of Mercury. At its minimum distance to the Sun of 0.1331 AU, it comes more than twice as close to the Sun as Mercury's perihelion at 0.307499 AU. This puts its nearest approach well within the hypothesized Vulcanoid Zone.

Orbit

A vulcanoid is an asteroid in a stable orbit with a semi-major axis less than that of Mercury (i.e. 0.387  AU). [7] [17] This does not include objects like sungrazing comets, which, although they have perihelia inside the orbit of Mercury, have far greater semi-major axes. [7]

The vulcanoids are thought to exist in a gravitationally stable band inside the orbit of Mercury, at distances of 0.060.21 AU from the Sun. [18] All other similarly stable regions in the Solar System have been found to contain objects, [8] although non-gravitational forces such as radiation pressure, [9] Poynting–Robertson drag [18] and the Yarkovsky effect [5] may have depleted the vulcanoid area of its original contents. There may be no more than 300900 vulcanoids larger than 1 kilometre (0.62 mi) in radius remaining, if any. [19] A 2020 study found that the Yarkovsky–O'Keefe–Radzievskii–Paddack effect is strong enough to destroy hypothetical vulcanoids as large as 100 km in radius on timescales far smaller than the age of the Solar System; would-be vulcanoid asteroids were found to be steadily spun up by the YORP effect until they rotationally fission into smaller bodies, which occurs repeatedly until the debris is small enough to be pushed out of the vulcanoid region by the Yarkovsky effect; this would explain why no vulcanoids have been observed. [20] The gravitational stability of the vulcanoid zone is due in part to the fact that there is only one neighbouring planet. In that respect it can be compared to the Kuiper belt. [18]

The outer edge of the vulcanoid zone is approximately 0.21 AU from the Sun. Objects more distant than this are unstable due to interactions with Mercury and would be perturbed into Mercury-crossing orbits on timescales of the order of 100 million years. [18] (Some definitions would nonetheless include such unstable objects as vulcanoids as long as their orbits lie completely interior to that of Mercury.) [21] The inner edge is not sharply defined: objects closer than 0.06 AU are particularly susceptible to Poynting–Robertson drag and the Yarkovsky effect, [18] and even out to 0.09 AU vulcanoids would have temperatures of 1,000  K or more, which is hot enough for evaporation of rocks to become the limiting factor in their lifetime. [22]

The maximum possible volume of the vulcanoid zone is very small compared to that of the asteroid belt. [22] Collisions between objects in the vulcanoid zone would be frequent and highly energetic, tending to lead to the destruction of the objects. The most favourable location for vulcanoids is probably in circular orbits near the outer edge of the vulcanoid zone. [23] Vulcanoids are unlikely to have inclinations of more than about 10° to the ecliptic. [7] [18] Mercury trojans, asteroids trapped in Mercury's Lagrange points, are also possible. [24]

Physical characteristics

Any vulcanoids that exist must be relatively small. Previous searches, particularly from the STEREO spacecraft, rule out asteroids larger than 6 kilometres (3.7 mi) in diameter. [14] The minimum size is about 100 metres (330 ft); [18] particles smaller than 0.2  μm are strongly repulsed by radiation pressure, and objects smaller than 70 m would be drawn into the Sun by Poynting–Robertson drag. [9] Between these upper and lower limits, a population of asteroids between 1 kilometre (0.62 mi) and 6 kilometres (3.7 mi) in diameter is thought to be possible. [10] They would be almost hot enough to glow red hot. [17]

It is thought that the vulcanoids would be very rich in elements with a high melting point, such as iron and nickel. They are unlikely to possess a regolith because such fragmented material heats and cools more rapidly, and is affected more strongly by the Yarkovsky effect, than solid rock. [5] Vulcanoids are probably similar to Mercury in colour and albedo, [7] and may contain material left over from the earliest stages of the Solar System's formation. [12]

There is evidence that Mercury was struck by a large object relatively late in its development, [5] a collision which stripped away much of Mercury's crust and mantle, [16] and explaining the thinness of Mercury's mantle compared to the mantles of the other terrestrial planets. If such an impact occurred, much of the resulting debris might still be orbiting the Sun in the vulcanoid zone. [13]

Significance

Vulcanoids, being an entirely new class of celestial bodies, would be interesting in their own right, [24] but discovering whether or not they exist would yield insights into the formation and evolution of the Solar System. If they exist they might contain material left over from the earliest period of planet formation, [12] and help determine the conditions under which the terrestrial planets, particularly Mercury, formed. [24] In particular, if vulcanoids exist or did exist in the past, they would represent an additional population of impactors that have affected no other planet but Mercury, [16] making that planet's surface appear older than it actually is. [24] If vulcanoids are found not to exist, this would place different constraints on planet formation [24] and suggest that other processes have been at work in the inner Solar System, such as planetary migration clearing out the area. [18]

See also

Related Research Articles

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<span class="mw-page-title-main">Vulcan (hypothetical planet)</span> Hypothetical planet between the Sun and Mercury

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References

  1. Drobyshevskii, E. M. (1992). "Impact Avalanche Ejection of Silicates from Mercury and the Evolution of the Mercury / Venus System". Soviet Astr. 36 (4): 436–443. Bibcode:1992SvA....36..436D.
  2. Standage, Tom (2000). The Neptune File. Harmondsworth, Middlesex, England: Allen Lane, The Penguin Press. pp. 144–149. ISBN   0-7139-9472-X.
  3. Miller, Ron (2002). Extrasolar Planets. Twenty-First Century Books. p. 14. ISBN   978-0-7613-2354-9.
  4. 1 2 3 "Vulcanoids". The Planetary Society. Archived from the original on 2009-01-08. Retrieved 2008-12-25.
  5. 1 2 3 4 Roach, John (2002). "Fighter Jet Hunts for "Vulcanoid" Asteroids". National Geographic News. Archived from the original on May 8, 2002. Retrieved 2008-12-24.
  6. Campbell, W.W.; Trumpler, R. (1923). "Search for Intramercurial Objects". Publications of the Astronomical Society of the Pacific. 35 (206): 214. Bibcode:1923PASP...35..214C. doi:10.1086/123310. S2CID   122872992.
  7. 1 2 3 4 5 "FAQ: Vulcanoid Asteroids". vulcanoid.org. 2005. Archived from the original on July 24, 2008. Retrieved 2008-12-27.
  8. 1 2 Britt, Robert Roy (2004). "Vulcanoid search reaches new heights". Space.com. Archived from the original on October 19, 2015. Retrieved 2008-12-25.
  9. 1 2 3 Schumacher, G.; Gay, J. (2001). "An Attempt to detect Vulcanoids with SOHO/LASCO images". Astronomy & Astrophysics. 368 (3): 1108–1114. Bibcode:2001A&A...368.1108S. doi: 10.1051/0004-6361:20000356 .
  10. 1 2 Whitehouse, David (2002-06-27). "Vulcan in the Twilight Zone". BBC News. Retrieved 2008-12-25.
  11. David, Leonard (2000). "Astronomers Eye 'Twilight Zone' Search for Vulcanoids". Space.com. Archived from the original on July 24, 2008. Retrieved 2008-12-25.
  12. 1 2 3 "NASA Dryden, Southwest Research Institute Search for Vulcanoids". NASA. 2002. Archived from the original on 2019-05-03. Retrieved 2008-12-25.
  13. 1 2 3 Alexander, Amir (2004). "Small, Faint, and Elusive: The Search for Vulcanoids". The Planetary Society. Archived from the original on 2008-10-11. Retrieved 2008-12-25.
  14. 1 2 3 Steffl, A. J.; Cunningham, N. J.; Shinn, A. B.; Stern, S. A. (2013). "A Search for Vulcanoids with the STEREO Heliospheric Imager". Icarus. 233 (1): 48–56. arXiv: 1301.3804 . Bibcode:2013Icar..223...48S. doi:10.1016/j.icarus.2012.11.031. S2CID   118612132.
  15. Choi, Charles Q. (2008). "The Enduring Mysteries of Mercury". Space.com. Retrieved 2008-12-25.
  16. 1 2 3 Chapman, C.R.; Merline, W.J.; Solomon, S.C.; Head, J.W. III; Strom, R.G. (2008), First MESSENGER Insights Concerning the Early Cratering History of Mercury (PDF), Lunar and Planetary Institute, retrieved 2008-12-26
  17. 1 2 Noll, Landon Curt (2007). "Vulcanoid Search during a Solar eclipse" . Retrieved 2008-12-24.
  18. 1 2 3 4 5 6 7 8 Evans, N. Wyn; Tabachnik, Serge (1999). "Possible Long-Lived Asteroid Belts in the Inner Solar System". Nature. 399 (6731): 41–43. arXiv: astro-ph/9905067 . Bibcode:1999Natur.399...41E. doi:10.1038/19919. S2CID   4418335.
  19. Vokrouhlický, David; Farinella, Paolo; Bottke, William F. Jr. (2000). "The Depletion of the Putative Vulcanoid Population via the Yarkovsky Effect". Icarus. 148 (1): 147–152. Bibcode:2000Icar..148..147V. doi:10.1006/icar.2000.6468. S2CID   55356387.
  20. Collins, M. D. (2020). "The YORP Effect Can Efficiently Destroy 100 Kilometer Planetesimals at the Inner Edge of the Solar System". American Astronomical Society Meeting Abstracts #235. 235: 277.01. Bibcode:2020AAS...23527701C.
  21. Greenstreet, Sarah; Ngo, Henry; Gladman, Brett (January 2012). "The orbital distribution of Near-Earth Objects inside Earth's orbit" (PDF). Icarus. 217 (1): 355–366. Bibcode:2012Icar..217..355G. doi:10.1016/j.icarus.2011.11.010. hdl: 2429/37251 . The existence of a non-negligible population of Venus-decoupled Vatiras thus begs the question as to whether any objects reach orbits entirely interior to that of Mercury. Accepted convention would likely to be to call such an object a Vulcanoid, although the term is usually intended to mean an object which has been resident inside Mercury for the entire lifetime of the Solar System.
  22. 1 2 Lewis, John S. (2004). Physics and Chemistry of the Solar System. Academic Press. p. 409. ISBN   978-0-12-446744-6.
  23. Stern, S.A.; Durda, D.D. (2000). "Collisional Evolution in the Vulcanoid Region: Implications for Present-Day Population Constraints". Icarus. 143 (2): 360. arXiv: astro-ph/9911249 . Bibcode:2000Icar..143..360S. doi:10.1006/icar.1999.6263. S2CID   11176435.
  24. 1 2 3 4 5 Campins, H.; Davis, D. R.; Weidenschilling, S. J.; Magee, M. (1996). "Searching for Vulcanoids". Completing the Inventory of the Solar System, Astronomical Society of the Pacific Conference Proceedings. 107: 85–96. Bibcode:1996ASPC..107...85C.

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