4 Vesta

4 Vesta  
Rheasilvia crater covers much of the southern hemisphere of Vesta. Taken by the Dawn spacecraft
Discovery
Discovered by Heinrich Wilhelm Olbers
Discovery date March 29, 1807
Designations
Pronunciation /ˈvɛstə/, Latin: Vesta
Named after Vesta
Minor planet
category		 Main belt (Vesta family)
Adjective Vestian, Vestan
Epoch May 14, 2008 (JD 2454600.5)
Aphelion 2.572 AU (384.72 Gm)
Perihelion 2.151 AU (321.82 Gm)
Semi-major axis 2.361 AU (353.268 Gm)
Eccentricity 0.089 17
Orbital period 3.63 a (1325.15 d)
Average orbital speed 19.34 km/s
Mean anomaly 90.53°
Inclination 7.135° to Ecliptic
5.56° to Invariable plane[2]
Longitude of ascending node 103.91°
Argument of perihelion 149.83°
Proper semi-major axis 2.3615126 AU
Proper eccentricity 0.0987580
Proper inclination 6.3923416°
Proper mean motion 99.188833 deg/yr
Proper orbital period 3.62944 yr
(1325.653 d)
Precession of perihelion 36.872897 arcsec/yr
Precession of the ascending node −39.597863 arcsec/yr
Physical characteristics
Dimensions 578×560×458 km[3]
529 km (mean)
Mass 2.59×1020 kg[5]
Mean density 3.42 g/cm³[6]
Equatorial surface gravity 0.22 m/s2
0.022 g
Escape velocity 0.35 km/s
Rotation period 0.222 6 d (5.342 h)[1][7]
Albedo 0.423 (geometric)[8]
Temperature min: 85 K (−188 °C)
max: 270 K (−3 °C)[9]
Spectral type V-type asteroid[1][10]
Apparent magnitude 5.1[11] to 8.48
Absolute magnitude (H) 3.20[1][8]
Angular diameter 0.64" to 0.20"

Vesta, formally designated 4 Vesta, is one of the largest asteroids, with a mean diameter of about 530 kilometres (330 mi).[1] It was discovered by Heinrich Wilhelm Olbers on March 29, 1807,[1] and is named after the Roman virgin goddess of home and hearth, Vesta.

Vesta is the second-most-massive asteroid after the dwarf planet Ceres,[12][13][14][15][16][17][18] and comprises an estimated 9% of the mass of the asteroid belt.[19] The less-massive Pallas might have a larger volume, which would make Vesta third in overall size, but the precise dimensions of Pallas are not known. Vesta is thought to be a remnant protoplanet with a differentiated interior.[20][21] It lost some 1% of its mass less than a billion years ago in a collision that left an enormous crater occupying much of its southern hemisphere. Debris from this event has fallen to Earth as Howardite–Eucrite–Diogenite (HED) meteorites, a rich source of information about the asteroid.[22][23]

Vesta is the brightest asteroid visible from Earth. Its maximum distance from the Sun is slightly farther than the minimum distance of Ceres from the Sun,[24] though its orbit lies entirely within the Cererian orbit.[25]

NASA's Dawn spacecraft entered orbit around Vesta on July 16, 2011 for a planned one-year exploration, and what is known about Vesta will be refined and extended as data from Dawn is received, analyzed and published.

Contents

Discovery

Heinrich Olbers discovered Pallas in 1802, the year after the discovery of Ceres. He proposed that the two objects were the remnants of a destroyed planet. He sent a letter with his proposal to the English astronomer William Herschel, suggesting that a search near the locations where the orbits of Ceres and Pallas intersected might reveal more fragments. These orbital intersections were located in the constellations of Cetus and Virgo.[26] Olbers commenced his search in 1802, and on March 29, 1807 he discovered Vesta in the constellation Virgo—a coincidence, as Ceres, Pallas, and Vesta are not fragments of a larger body. As the asteroid Juno had been discovered in 1804, this made Vesta the fourth object to be identified in the region that is now known as the asteroid belt. The discovery was announced in a letter addressed to German astronomer Johann H. Schröter dated March 31.[27] Because he already had credit for discovering a planet, Pallas, Olbers gave the honor of naming his new discovery to German mathematician Carl Friedrich Gauss, whose orbital calculations had enabled astronomers to confirm the existence of Ceres, the first asteroid, and who had computed the orbit of the new planet in the remarkably short time of 10 hours.[28][29] Gauss decided on the Roman virgin goddess of home and hearth, Vesta.[30]

Nomenclature

Vesta was the fourth asteroid to be discovered, hence the number 4 in its formal designation. The name Vesta, or national variants thereof, is in international use with two exceptions, Greece and China. In Greek the name adopted was the Hellenic equivalent of Vesta, Hestia (4 Εστία); in English, that name is used for 46 Hestia (Greeks use the name "Hestia" for both, with the asteroid numbers used for disambiguation). In Chinese, Vesta is called the 'hearth-god(dess) star', 灶神星 zàoshénxīng, in contrast to the goddess Vesta, who goes by her Latin name.[31]

When Olbers discovered Vesta, Ceres, Pallas, and Juno were classified as planets and each had its own planetary symbol. Vesta was likewise classified as a planet, and along with its name, Gauss designed an appropriate planetary symbol, , the altar of the Vesta with its sacred fire.[32][33] In Gauss's conception this was drawn ; in its modern form it is .[note 1]

After the discovery of Vesta, no further objects were discovered for 38 years, and the Solar System was thought to have eleven planets.[36] However, in 1845 new asteroids started being discovered at a rapid pace, and by 1851 there were fifteen, each with its own symbol, in addition to the seven major planets. It soon became clear that it would be impractical to continue inventing new planetary symbols indefinitely, and some of the existing ones proved difficult to draw quickly. That year the problem was addressed by Benjamin Apthorp Gould, who suggested numbering asteroids in their order of discovery, and placing this number in a disk (circle) as the generic symbol of an asteroid. Thus the fourth asteroid, Vesta, acquired the generic symbol ④. This was soon coupled with the name into an official number–name designation, ④ Vesta, as the number of minor planets increased. By ca 1858, the circle had been simplified to parentheses, (4) and (4) Vesta, which was easier to typeset. Other punctuation such as 4) Vesta and 4, Vesta was also used, but had more or less completely died out by 1949.[37] Today either (4) Vesta or more commonly 4 Vesta is used.

Early measurements

Photometric observations of the asteroid Vesta were made at the Harvard College Observatory in 1880–82 and at the Observatoire de Toulouse in 1909. These and other observations allowed the rotation rate of the asteroid to be determined by the 1950s. However, the early estimates of the rotation rate came into question because the light curve included variations in both shape and albedo.[38]

Early estimates of the diameter of Vesta ranged from 383 (in 1825) to 444 km. E.C. Pickering produced an estimated diameter of 513 ± 17 km in 1879, which is close to the modern value for the mean diameter, but the subsequent estimates ranged from a low of 390 km up to a high of 602 km during the next century. The measured estimates were based on photometry. In 1989, speckle interferometry was used to measure a dimension that varied between 498 and 548 km during the rotational period.[39] In 1991, an occultation of the star SAO 93228 by Vesta was observed from multiple locations in the eastern US and Canada. Based on observations from 14 different sites, the best fit to the data is an elliptical profile with dimensions of about 550 km × 462 km.[40]

Vesta became the first asteroid to have its mass determined. Every 18 years, the asteroid 197 Arete approaches within 0.04 AU of Vesta. In 1966, based upon observations of Vesta's gravitational perturbations of Arete, Hans G. Hertz estimated the mass of Vesta as (1.20 ± 0.08) × 10−10 solar masses.[41] More refined estimates followed, and in 2001 the perturbations of 17 Thetis were used to estimate the mass of Vesta as (1.31 ± 0.02) × 10−10 solar masses.[42]

Physical characteristics

Vesta is the second-most-massive body in the asteroid belt,[6] though only 28% as massive as Ceres.[19] It orbits in the inner asteroid belt interior to the Kirkwood gap at 2.50 AU. It has a differentiated interior,[20] and is similar to 2 Pallas in volume (to within uncertainty) but about 25% more massive.[6]

Vesta's shape is relatively close to a gravitationally relaxed oblate spheroid,[44] but the large concavity and protrusion at the pole (see 'Surface features' below) combined with a mass less than 5×1020 kg precluded Vesta from automatically being considered a dwarf planet under International Astronomical Union (IAU) Resolution XXVI 5.[45] Vesta may be listed as a dwarf planet in the future, if it is convincingly determined that its shape, other than the large impact basin at the southern pole, is due to hydrostatic equilibrium, as currently believed.[20]

Its rotation is relatively fast for an asteroid (5.342 h) and prograde, with the north pole pointing in the direction of right ascension 20 h 32 min, declination +48° (in the constellation Cygnus) with an uncertainty of about 10°. This gives an axial tilt of 29°.[44]

Temperatures on the surface have been estimated to lie between about −20 °C with the Sun overhead, dropping to about −190 °C at the winter pole. Typical daytime and nighttime temperatures are −60 °C and −130 °C, respectively. This estimate is for May 6, 1996, very close to perihelion, while details vary somewhat with the seasons.[9]

Surface features

Prior to the arrival of the Dawn spacecraft, some Vestian surface features had already been resolved using the Hubble Space Telescope and ground based telescopes (e.g. the Keck Observatory).[46]

The eastern and western hemispheres show markedly different terrains. From preliminary spectral analyses of the Hubble Space Telescope images,[47] the eastern hemisphere appears to be some kind of high-albedo, heavily cratered "highland" terrain with aged regolith, and craters probing into deeper plutonic layers of the crust. On the other hand, large regions of the western hemisphere are taken up by dark geologic units thought to be surface basalts, perhaps analogous to the lunar maria.[47]

Rheasilvia crater

Main article: Rheasilvia

The most prominent of these surface features is an enormous crater 460 kilometres (290 mi) in diameter centered near the south pole.[44] The Dawn science team has named it Rheasilvia, after the mother of Romulus and Remus and a mythical vestal virgin.[48] Its width is 80% the diameter of Vesta. The floor of this crater is about 13 kilometres (8.1 mi) below, and its rim rises 4–12 km above the surrounding terrain, with total surface relief of about 25 km. A central peak rises 23 km above the lowest measured part of the crater floor and the highest measured part of the crater rim is 31 km above the crater floor low point. It is estimated that the impact responsible excavated about 1% of the volume of Vesta, and it is likely that the Vesta family and V-type asteroids are the products of this collision. If this is the case, then the fact that 10-km fragments have survived bombardment until the present indicates that the crater is at most only about 1 billion years old.[47] It would also be the original site of origin of the HED meteorites. In fact, all the known V-type asteroids taken together account for only about 6% of the ejected volume, with the rest presumably either in small fragments, ejected by approaching the 3:1 Kirkwood gap, or perturbed away by the Yarkovsky effect or radiation pressure. Spectroscopic analyses of the Hubble images have shown that this crater has penetrated deep through several distinct layers of the crust, and possibly into the mantle, as indicated by spectral signatures of olivine.[44]

The southern polar region has a mountain that is 13 miles (21 km) high.[49][50][51]

Other craters

Several other large craters about 150 kilometres (93 mi) wide and 7 kilometres (4.3 mi) deep are also present. A dark albedo feature about 200 kilometres (120 mi) across has been named Olbers in honour of Vesta's discoverer, but it does not appear in elevation maps as a fresh crater would. Its nature is presently unknown; it may be an old basaltic surface.[52] It serves as a reference point with the 0° longitude prime meridian defined to pass through its center.

"Snowman craters"

The "snowman craters" is an informal name given to a group of three adjacent craters in Vesta's northern hemisphere. The largest of the three is officially named Marcia.

"Snowman" craters by Dawn from 5,200 km (3,200 mi) in 2011
August 6, 2011
Detailed image of the "Snowman" craters

Equatorial grooves

The southern equatorial region of Vesta is characterized by a series of concentric grooves. These are thought to be compression fractures from the impact that created Rheasilvia crater. If they are continuous features, they would be one of the longer chasms in the Solar System, nearly as long as Ithaca Chasma on Tethys.

Snowman craters on left
Zoom in on Southern equatorial region

Geology

There is a large collection of potential samples from Vesta accessible to scientists, in the form of over 200 HED meteorites, giving insight into Vesta's geologic history and structure. NASA Infrared Telescope Facility (NASA IRTF) studies of asteroid (237442) 1999 TA10 suggest that it originated from the interior of Vesta.[21][53]

Vesta is thought to consist of a metallic ironnickel core, an overlying rocky olivine mantle, with a surface crust. From the first appearance of Ca-Al-rich inclusions (the first solid matter in the Solar System, forming about 4,567 million years ago), a likely time line is as follows:[54][55][56][57][58]

Timeline of the evolution of Vesta
2–3 million years Accretion completed
4–5 million years Complete or almost complete melting due to radioactive decay of 26Al, leading to separation of the metal core
6–7 million years Progressive crystallization of a convecting molten mantle. Convection stopped when about 80% of the material had crystallized
Extrusion of the remaining molten material to form the crust, either as basaltic lavas in progressive eruptions, or possibly forming a short-lived magma ocean.
The deeper layers of the crust crystallize to form plutonic rocks, while older basalts are metamorphosed due to the pressure of newer surface layers.
Slow cooling of the interior

Vesta is the only known intact asteroid that has been resurfaced in this manner. Because of this, some scientists refer to Vesta as a protoplanet, rather than an asteroid.[59] However, the presence of iron meteorites and achondritic meteorite classes without identified parent bodies indicates that there once were other differentiated planetesimals with igneous histories, which have since been shattered by impacts.

Composition of the Vestian crust (by depth)[60]
A lithified regolith, the source of howardites and brecciated eucrites.
Basaltic lava flows, a source of non-cumulate eucrites.
Plutonic rocks consisting of pyroxene, pigeonite and plagioclase, the source of cumulate eucrites.
Plutonic rocks rich in orthopyroxene with large grain sizes, the source of diogenites.

On the basis of the sizes of V-type asteroids (thought to be pieces of Vesta's crust ejected during large impacts), and the depth of the south polar crater (see below), the crust is thought to be roughly 10 kilometres (6 mi) thick.[61]

Fragments

Some small Solar System bodies are believed to be fragments of Vesta caused by collisions. The Vestian asteroids and HED meteorites are examples. The V-type asteroid 1929 Kollaa has been determined to have a composition akin to cumulate eucrite meteorites, indicating its origin deep within Vesta's crust.[22]

Because a number of meteorites are believed to be Vestian fragments, Vesta is currently one of only six identified Solar System bodies for which we have physical samples, the others being Mars, the Moon, comet Wild 2, 25143 Itokawa, and Earth itself.[23]

Exploration

Dawn spacecraft art

In 1981, a proposal for an asteroid mission was submitted to the European Space Agency (ESA). Named the Asteroidal Gravity Optical and Radar Analysis (AGORA), this spacecraft was to launch some time in 1990–1994 and perform two flybys of large asteroids. The preferred target for this mission was Vesta. AGORA would reach the asteroid belt either by a gravitational slingshot trajectory past Mars or by means of a small ion engine. However, the proposal was refused by the ESA. A joint NASA–ESA asteroid mission was then drawn up for a Multiple Asteroid Orbiter with Solar Electric Propulsion (MAOSEP), with one of the mission profiles including an orbit of Vesta. NASA indicated they were not interested in an asteroid mission. Instead, the ESA set up a technological study of a spacecraft with an ion drive. Other missions to the asteroid belt were proposed in the 1980s by France, Germany, Italy and the United States, but none were approved.[62] Exploration of Vesta by fly-by and impacting penetrator was the second main target of the first plan of the multiaimed Soviet Vesta mission, developed in cooperation with European countries for realisation in 1991–1994 but canceled due to the Soviet Union disbanding.

In the early 1990s, NASA initiated the Discovery Program, which was intended to be a series of low-cost scientific missions. In 1996, the program's study team recommended as a high priority a mission to explore the asteroid belt using a spacecraft with an ion engine. Funding for this program remained problematic for several years, but by 2004 the Dawn vehicle had passed its critical design review.[63]

It launched on September 27, 2007, as the first space mission to Vesta. It is planned to orbit the asteroid for one year, from July 16, 2011 until July 2012.[64] This will coincide with late summer in the southern hemisphere of Vesta, so the large crater at the south pole will be in sunlight; since a season on Vesta lasts eleven months, the northern hemisphere, including anticipated compression fractures opposite the crater, will become visible to Dawn's cameras before it leaves orbit.[65]

On May 3, 2011, Dawn acquired its first targeting image 1.2 million kilometers from Vesta.[66] On July 16, 2011, NASA confirmed that it received telemetry from Dawn indicating that the spacecraft successfully entered Vesta's orbit.[67]

Scientists will use Dawn to calculate Vesta's precise mass based on gravitational interactions. This will allow scientists to refine the mass estimates of the asteroids that are in turn perturbed by Vesta.[63]

NASA/DRL released imagery and summary information from a high-altitude orbit, including a two-minute video, in September 2011. Much more detailed imagery will begin to be obtained, from a lower orbit, beginning in October 2011.[68]

Observations from Earth orbit

Observations from Dawn

Vesta comes into view as Dawn approaches and enters orbit:

Visibility

Its size and unusually bright surface make Vesta the brightest asteroid, and it is occasionally visible to the naked eye from dark skies (without light pollution). In May and June 2007, Vesta reached a peak magnitude of +5.4, the brightest since 1989.[69] At that time, opposition and perihelion were only a few weeks apart. It was visible in the constellations Ophiuchus and Scorpius.[70]

Less favorable oppositions during late autumn 2008 in the Northern Hemisphere still had Vesta at a magnitude of from +6.5 to +7.3.[71] Even when in conjunction with the Sun, Vesta will have a magnitude around +8.5; thus from a pollution-free sky it can be observed with binoculars even at elongations much smaller than near opposition.[71]

2010–2011

In 2010, Vesta reached opposition in the constellation of Leo on the night of February 17–18, when it was about magnitude 6.1,[72] a brightness that makes it visible in binocular range but not for the naked eye. Under perfect dark sky conditions where all light pollution is absent it might be visible to an experienced observer without the use of a telescope or binoculars. Vesta came to opposition again on August 5, 2011, in the constellation of Capricornus at about magnitude 5.6.[72][73]

See also

Notes and references

Notes

  1. ^ Other sources contemporaneous to Gauss used a more elaborate form of the symbol, .[34][35]

Footnotes

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  2. ^ "The MeanPlane (Invariable plane) of the Solar System passing through the barycenter". 2009-04-03. http://home.comcast.net/~kpheider/MeanPlane.gif. Retrieved 2009-04-10.  (produced with Solex 10 written by Aldo Vitagliano; see also Invariable plane)
  3. ^ Thomas, P. C.; et al. (1997). "Impact excavation on asteroid 4 Vesta: Hubble Space Telescope results". Science 277 (5331): 1492. Bibcode 1997Sci...277.1492T. doi:10.1126/science.277.5331.1492. 
  4. ^ "AstDyS-2 Vesta Synthetic Proper Orbital Elements". Department of Mathematics, University of Pisa, Italy. http://hamilton.dm.unipi.it/astdys/index.php?pc=1.1.6&n=4. Retrieved 2011-10-01. 
  5. ^ Dawn Journal at the DAWN website of JPL
  6. ^ a b c Baer, James; Chesley, Steven R. (2008). "Astrometric masses of 21 asteroids, and an integrated asteroid ephemeris" (PDF). Celestial Mechanics and Dynamical Astronomy (Springer Science+Business Media B.V. 2007) 100 (2008): 27–42. Bibcode 2008CeMDA.100...27B. doi:10.1007/s10569-007-9103-8. http://www.springerlink.com/content/h747307j43863228/fulltext.pdf. Retrieved 2008-11-11. 
  7. ^ Harris, A. W.; Warner, B. D.; Pravec, P.; (Eds.) (2006). "Asteroid Lightcurve Derived Data. EAR-A-5-DDR-DERIVED-LIGHTCURVE-V8.0.". NASA Planetary Data System. Archived from the original on 2007-01-28. http://web.archive.org/web/20070128183706/http://www.psi.edu/pds/resource/lc.html. Retrieved 2007-03-15. 
  8. ^ a b Tedesco, E. F.; Noah, P. V.; Noah, M.; Price, S. D. (2004). "Infra-Red Astronomy Satellite (IRAS) Minor Planet Survey. IRAS-A-FPA-3-RDR-IMPS-V6.0.". NASA Planetary Data System. Archived from the original on 2007-03-11. http://web.archive.org/web/20070311123634/http://www.psi.edu/pds/resource/imps.html. Retrieved 2007-03-15. 
  9. ^ a b Mueller, T. G.; Metcalfe, L. (2001). "ISO and Asteroids". European Space Agency (ESA) bulletin 108: 38. http://www.esa.int/esapub/bulletin/bullet108/chapter4_bul108.pdf. 
  10. ^ Neese, C.; Ed. (2005). "Asteroid Taxonomy EAR-A-5-DDR-TAXONOMY-V5.0". NASA Planetary Data System. Archived from the original on 2007-03-10. http://web.archive.org/web/20070310220044/http://www.psi.edu/pds/resource/taxonomy.html. Retrieved 2007-03-15. 
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  15. ^ Lang, Kenneth (2011). The Cambridge Guide to the Solar System. Cambridge University Press. pp. 372, 442. 
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  18. ^ Russell et al. 2011. "Exploring the smallest terrestrial planet: Dawn at Vesta"
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  20. ^ a b c Savage, Don; Jones, Tammy; and Villard, Ray (1995). "Asteroid or Mini-Planet? Hubble Maps the Ancient Surface of Vesta". Hubble Site News Release STScI-1995-20. http://hubblesite.org/newscenter/archive/releases/1995/20/image/c. Retrieved 2006-10-17. 
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  24. ^ On February 10, 2009, during Ceres perihelion, Ceres was closer to the Sun than Vesta, since Vesta has an aphelion distance greater than Ceres' perihelion distance. (2009-02-10: Vesta 2.56AU; Ceres 2.54AU)
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  30. ^ Schmadel, Lutz D. (2003). Dictionary of Minor Planet Names: Prepared on Behalf of Commission 20 Under the Auspices of the International Astronomical Union. Springer. p. 15. ISBN 3-540-00238-3. 
  31. ^ 維斯塔 wéisītǎ is the Chinese approximation of the Latin pronunciation.
  32. ^ von Zach, Franz Xaver (1807). Monatliche correspondenz zur beförderung der erd- und himmels-kunde, Volume 15. p. 507. http://books.google.com/books?id=_Rw4AAAAMAAJ&pg=PA507. 
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  37. ^ From Dr. James Hilton's When Did the Asteroids Become Minor Planets?, particularly the discussion of Gould, B. A. 1852, On the Symbolic Notation of the Asteroids, Astronomical Journal, Vol. 2, and immediately subsequent history. The discussion of C. J. Cunningham (1988), also from there, explains the parenthetical part.
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General references

  • Yeomans, Donald K.. "Horizons system". NASA JPL. http://ssd.jpl.nasa.gov/?horizons. Retrieved 2007-03-20.  – Horizons can be used to obtain a current ephemeris
  • Keil, K.; Geological History of Asteroid 4 Vesta: The Smallest Terrestrial Planet in Asteroids III, William Bottke, Alberto Cellino, Paolo Paolicchi, and Richard P. Binzel, (Editors), University of Arizona Press (2002), ISBN 0-8165-2281-2

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