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243 Ida

January 01, 1970

This article is about an asteroid. For other uses, see Ida (disambiguation).

Ida, minor planet designation 243 Ida, is an asteroid in the Koronis family of the asteroid belt. It was discovered on 29 September 1884 by Austrian astronomer Johann Palisa at Vienna Observatory and named after a nymph from Greek mythology. Later telescopic observations categorized Ida as an S-type asteroid, the most numerous type in the inner asteroid belt. On 28 August 1993, Ida was visited by the uncrewed Galileo spacecraft while en route to Jupiter. It was the second asteroid visited by a spacecraft and the first found to have a natural satellite.

Ida
Galileo image of 243 Ida. The dot to the right is its moon Dactyl.
Discovery[1]
Discovered byJohann Palisa
Discovery siteVienna Observatory
Discovery dateSeptember 29, 1884
Designations
(243) Ida
Pronunciation/ˈdə/[2]
Named after
Ida (nurse of Zeus)
Main belt (Koronis family)[3]
AdjectivesIdean (Idæan) /ˈdən/[4]
Orbital characteristics[5]
Epoch 31 July 2016 (JD 2457600.5)
Aphelion2.979 AU (4.457×1011 m)
Perihelion2.743 AU (4.103×1011 m)
2.861 AU (4.280×1011 m)
Eccentricity0.0411
1,767.644 days (4.83955 a)
0.2036°/d
38.707°
Inclination1.132°
324.016°
110.961°
Known satellitesDactyl
Physical characteristics
Dimensions59.8 × 25.4 × 18.6 km[6]
Mean radius
15.7 km[7]
Mass4.2 ± 0.6 ×1016 kg[7]
Mean density
2.6 ± 0.5 g/cm3[8]
Equatorial surface gravity
0.3–1.1 cm/s2[9]
4.63 hours (0.193 d)[10]
North pole right ascension
168.76°[11]
North pole declination
−2.88°[11]
0.2383[5]
Temperature200 K (−73 °C)[3]
S[12]
9.94[5]

Ida's orbit lies between the planets Mars and Jupiter, like all main-belt asteroids. Its orbital period is 4.84 years, and its rotation period is 4.63 hours. Ida has an average diameter of 31.4 km (19.5 mi). It is irregularly shaped and elongated, apparently composed of two large objects connected together. Its surface is one of the most heavily cratered in the Solar System, featuring a wide variety of crater sizes and ages.

Ida's moon Dactyl was discovered by mission member Ann Harch in images returned from Galileo. It was named after the Dactyls, creatures which inhabited Mount Ida in Greek mythology. Dactyl is only 1.4 kilometres (0.87 mi) in diameter, about 1/20 the size of Ida. Its orbit around Ida could not be determined with much accuracy, but the constraints of possible orbits allowed a rough determination of Ida's density and revealed that it is depleted of metallic minerals. Dactyl and Ida share many characteristics, suggesting a common origin.

The images returned from Galileo and the subsequent measurement of Ida's mass provided new insights into the geology of S-type asteroids. Before the Galileo flyby, many different theories had been proposed to explain their mineral composition. Determining their composition permits a correlation between meteorites falling to the Earth and their origin in the asteroid belt. Data returned from the flyby pointed to S-type asteroids as the source for the ordinary chondrite meteorites, the most common type found on the Earth's surface.

Discovery and observations edit

Ida was discovered on 29 September 1884 by Austrian astronomer Johann Palisa at the Vienna Observatory.[13] It was his 45th asteroid discovery.[1] Ida was named by Moriz von Kuffner, a Viennese brewer and amateur astronomer.[14][15] In Greek mythology, Ida was a nymph of Crete who raised the god Zeus.[16] Ida was recognized as a member of the Koronis family by Kiyotsugu Hirayama, who proposed in 1918 that the group comprised the remnants of a destroyed precursor body.[17]

Ida's reflection spectrum was measured on 16 September 1980 by astronomers David J. Tholen and Edward F. Tedesco as part of the eight-color asteroid survey (ECAS).[18] Its spectrum matched those of the asteroids in the S-type classification.[19][20] Many observations of Ida were made in early 1993 by the US Naval Observatory in Flagstaff and the Oak Ridge Observatory. These improved the measurement of Ida's orbit around the Sun and reduced the uncertainty of its position during the Galileo flyby from 78 to 60 km (48 to 37 mi).[21]

Exploration edit

 
Animation of Galileo's trajectory from 19 October 1989 to 30 September 2003
  Galileo ·   Jupiter ·   Earth ·    Venus ·   951 Gaspra ·   243 Ida
 
Trajectory of Galileo from launch to Jupiter orbital insertion

Galileo flyby edit

Ida was visited in 1993 by the Jupiter-bound space probe Galileo. Its encounters of the asteroids Gaspra and Ida were secondary to the Jupiter mission. These were selected as targets in response to a new NASA policy directing mission planners to consider asteroid flybys for all spacecraft crossing the belt.[22] No prior missions had attempted such a flyby.[23] Galileo was launched into orbit by the Space Shuttle Atlantis mission STS-34 on 18 October 1989.[24] Changing Galileo's trajectory to approach Ida required that it consume 34 kg (75 lb) of propellant.[25] Mission planners delayed the decision to attempt a flyby until they were certain that this would leave the spacecraft enough propellant to complete its Jupiter mission.[26]

 
Images from the flyby, starting 5.4 hours before closest approach and showing Ida's rotation

Galileo's trajectory carried it into the asteroid belt twice on its way to Jupiter. During its second crossing, it flew by Ida on 28 August 1993 at a speed of 12,400 m/s (41,000 ft/s) relative to the asteroid.[26] The onboard imager observed Ida from a distance of 240,350 km (149,350 mi) to its closest approach of 2,390 km (1,490 mi).[16][27] Ida was the second asteroid, after Gaspra, to be imaged by a spacecraft.[28] About 95% of Ida's surface came into view of the probe during the flyby.[9]

Transmission of many Ida images was delayed due to a permanent failure in the spacecraft's high-gain antenna.[29] The first five images were received in September 1993.[30] These comprised a high-resolution mosaic of the asteroid at a resolution of 31–38 m/pixel.[31][32] The remaining images were sent in February 1994,[3] when the spacecraft's proximity to the Earth allowed higher speed transmissions.[30][33]

Discoveries edit

The data returned from the Galileo flybys of Gaspra and Ida, and the later NEAR Shoemaker asteroid mission, permitted the first study of asteroid geology.[34] Ida's relatively large surface exhibited a diverse range of geological features.[35] The discovery of Ida's moon Dactyl, the first confirmed satellite of an asteroid, provided additional insights into Ida's composition.[36]

Ida is classified as an S-type asteroid based on ground-based spectroscopic measurements.[37] The composition of S-types was uncertain before the Galileo flybys, but was interpreted to be either of two minerals found in meteorites that had fallen to the Earth: ordinary chondrite (OC) and stony-iron.[12] Estimates of Ida's density are constrained to less than 3.2 g/cm3 by the long-term stability of Dactyl's orbit.[37] This all but rules out a stony-iron composition; were Ida made of 5 g/cm3 iron- and nickel-rich material, it would have to contain more than 40% empty space.[36]

The Galileo images also led to the discovery that space weathering was taking place on Ida, a process which causes older regions to become more red in color over time.[17][38] The same process affects both Ida and its moon, although Dactyl shows a lesser change.[39] The weathering of Ida's surface revealed another detail about its composition: the reflection spectra of freshly exposed parts of the surface resembled that of OC meteorites, but the older regions matched the spectra of S-type asteroids.[23]

 
Polished section of an ordinary chondrite meteorite

Both of these discoveries—the space weathering effects and the low density—led to a new understanding about the relationship between S-type asteroids and OC meteorites. S-types are the most numerous kind of asteroid in the inner part of the asteroid belt.[23] OC meteorites are, likewise, the most common type of meteorite found on the Earth's surface.[23] The reflection spectra measured by remote observations of S-type asteroids, however, did not match that of OC meteorites. The Galileo flyby of Ida found that some S-types, particularly the Koronis family, could be the source of these meteorites.[39]

Physical characteristics edit

 
Size comparison of Ida, several other asteroids, the dwarf planet Ceres, and Mars

Ida's mass is between 3.65 and 4.99 × 1016 kg.[40] Its gravitational field produces an acceleration of about 0.3 to 1.1 cm/s2 over its surface.[9] This field is so weak that an astronaut standing on its surface could leap from one end of Ida to the other, and an object moving in excess of 20 m/s (70 ft/s) could escape the asteroid entirely.[41][42]

 
Successive images of a rotating Ida

Ida is a distinctly elongated asteroid,[43] with an irregular surface.[44][45] Ida is 2.35 times as long as it is wide,[43] and a "waist" separates it into two geologically dissimilar halves.[30] This constricted shape is consistent with Ida being made of two large, solid components, with loose debris filling the gap between them. However, no such debris was seen in high-resolution images captured by Galileo.[45] Although there are a few steep slopes tilting up to about 50° on Ida, the slope generally does not exceed 35°.[9] Ida's irregular shape is responsible for the asteroid's very uneven gravitational field.[46] The surface acceleration is lowest at the extremities because of their high rotational speed. It is also low near the "waist" because the mass of the asteroid is concentrated in the two halves, away from this location.[9]

Surface features edit

 
Mosaic of images recorded by Galileo 3.5 minutes before its closest approach

Ida's surface appears heavily cratered and mostly gray, although minor color variations mark newly formed or uncovered areas.[16] Besides craters, other features are evident, such as grooves, ridges, and protrusions. Ida is covered by a thick layer of regolith, loose debris that obscures the solid rock beneath. The largest, boulder-sized, debris fragments are called ejecta blocks, several of which have been observed on the surface.

Regolith edit

The surface of Ida is covered in a blanket of pulverized rock, called regolith, about 50–100 m (160–330 ft) thick.[30] This material is produced in impact events and redistributed across Ida's surface by geological processes.[47] Galileo observed evidence of recent downslope regolith movement.[48]

Ida's regolith is composed of the silicate minerals olivine and pyroxene.[3][49] Its appearance changes over time through a process called space weathering.[39] Because of this process, older regolith appears more red in color compared to freshly exposed material.[38]

 
Galileo image of a 150 m (490 ft) block at 24.8°S, 2.8°E[50]

About 20 large (40–150 m across) ejecta blocks have been identified, embedded in Ida's regolith.[30][51] Ejecta blocks constitute the largest pieces of the regolith.[52] Because ejecta blocks are expected to break down quickly by impact events, those present on the surface must have been either formed recently or uncovered by an impact event.[46][53] Most of them are located within the craters Lascaux and Mammoth, but they may not have been produced there.[53] This area attracts debris due to Ida's irregular gravitational field.[46] Some blocks may have been ejected from the young crater Azzurra on the opposite side of the asteroid.[54]

Structures edit

Several major structures mark Ida's surface. The asteroid appears to be split into two halves, here referred to as region 1 and region 2, connected by a "waist".[30] This feature may have been filled in by debris, or blasted out of the asteroid by impacts.[30][54]

Region 1 of Ida contains two major structures. One is a prominent 40 km (25 mi) ridge named Townsend Dorsum that stretches 150 degrees around Ida's surface.[55] The other structure is a large indentation named Vienna Regio.[30]

Ida's region 2 features several sets of grooves, most of which are 100 m (330 ft) wide or less and up to 4 km (2.5 mi) long.[30][56] They are located near, but are not connected with, the craters Mammoth, Lascaux, and Kartchner.[52] Some grooves are related to major impact events, for example a set opposite Vienna Regio.[57]

Craters edit

Ida is one of the most densely cratered bodies yet explored in the Solar System,[31][44] and impacts have been the primary process shaping its surface.[58] Cratering has reached the saturation point, meaning that new impacts erase evidence of old ones, leaving the total crater count roughly the same.[59] It is covered with craters of all sizes and stages of degradation,[44] and ranging in age from fresh to as old as Ida itself.[30] The oldest may have been formed during the breakup of the Koronis family parent body.[39] The largest crater, Lascaux, is almost 12 km (7.5 mi) across.[45][60] Region 2 contains nearly all of the craters larger than 6 km (3.7 mi) in diameter, but Region 1 has no large craters at all.[30] Some craters are arranged in chains.[32]

 
Asymmetric 1.5 km (0.93 mi) wide crater Fingal at 13.2°S, 39.9°E[60]

Ida's major craters are named after caves and lava tubes on Earth. The crater Azzurra, for example, is named after a submerged cave on the island of Capri, also known as the Blue Grotto.[61] Azzurra seems to be the most recent major impact on Ida.[51] The ejecta from this collision is distributed discontinuously over Ida[38] and is responsible for the large-scale color and albedo variations across its surface.[62] An exception to the crater morphology is the fresh, asymmetric Fingal, which has a sharp boundary between the floor and wall on one side.[63] Another significant crater is Afon, which marks Ida's prime meridian.[11]

The craters are simple in structure: bowl-shaped with no flat bottoms and no central peaks.[63] They are distributed evenly around Ida, except for a protrusion north of crater Choukoutien which is smoother and less cratered.[64] The ejecta excavated by impacts is deposited differently on Ida than on planets because of its rapid rotation, low gravity and irregular shape.[43] Ejecta blankets settle asymmetrically around their craters, but fast-moving ejecta that escapes from the asteroid is permanently lost.[65]

Composition edit

Ida was classified as an S-type asteroid based on the similarity of its reflectance spectra with similar asteroids.[12] S-types may share their composition with stony-iron or ordinary chondrite (OC) meteorites.[12] The composition of the interior has not been directly analyzed, but is assumed to be similar to OC material based on observed surface color changes and Ida's bulk density of 2.27–3.10 g/cm3.[39][66] OC meteorites contain varying amounts of the silicates olivine and pyroxene, iron, and feldspar.[67] Olivine and pyroxene were detected on Ida by Galileo.[3] The mineral content appears to be homogeneous throughout its extent. Galileo found minimal variations on the surface, and the asteroid's spin indicates a consistent density.[68][69] Assuming that its composition is similar to OC meteorites, which range in density from 3.48 to 3.64 g/cm3, Ida would have a porosity of 11–42%.[66]

Ida's interior probably contains some amount of impact-fractured rock, called megaregolith. The megaregolith layer of Ida extends between hundreds of meters below the surface to a few kilometers. Some rock in Ida's core may have been fractured below the large craters Mammoth, Lascaux, and Undara.[69]

Orbit and rotation edit

 
Orbit and positions of Ida and five planets as of 9 March 2009

Ida is a member of the Koronis family of asteroid-belt asteroids.[17] Ida orbits the Sun at an average distance of 2.862 AU (428.1 Gm), between the orbits of Mars and Jupiter.[3][5] Ida takes 4.84089 years to complete one orbit.[5]

Ida's rotation period is 4.63 hours (roughly 5 hours),[10][43] making it one of the fastest rotating asteroids yet discovered.[70] The calculated maximum moment of inertia of a uniformly dense object the same shape as Ida coincides with the spin axis of the asteroid. This suggests that there are no major variations of density within the asteroid.[57] Ida's axis of rotation precesses with a period of 77 thousand years, due to the gravity of the Sun acting upon the nonspherical shape of the asteroid.[71]

Origin edit

Ida originated in the breakup of the roughly 120 km (75 mi) diameter Koronis parent body.[10] The progenitor asteroid had partially differentiated, with heavier metals migrating to the core.[72] Ida carried away insignificant amounts of this core material.[72] It is uncertain how long ago the disruption event occurred. According to an analysis of Ida's cratering processes, its surface is more than a billion years old.[72] However, this is inconsistent with the estimated age of the Ida–Dactyl system of less than 100 million years;[73] it is unlikely that Dactyl, due to its small size, could have escaped being destroyed in a major collision for longer. The difference in age estimates may be explained by an increased rate of cratering from the debris of the Koronis parent body's destruction.[74]

Dactyl edit

Dactyl
 
Highest-resolution image of Dactyl, recorded while Galileo was about 3,900 km away from the moon
Discovery
Discovered byAnn Harch
Discovery siteGalileo spacecraft
Discovery date17 February 1994
Designations
(243) Ida I Dactyl
Pronunciation/ˈdæktɪl/ DAK-til[75]
Named after
Dactyls
1993 (243) 1
AdjectivesDactylian /dækˈtɪliən/[76]
Orbital characteristics
90 km at time of discovery
prograde, ca. 20 h
Inclinationca. 8°[77]
Satellite ofIda
Physical characteristics
Dimensions1.6×1.4×1.2 km
synchronous
Temperature200 K (−73 °C; −100 °F)
Main article: Dactyl (moon)

Ida has a moon named Dactyl, official designation (243) Ida I Dactyl. It was discovered in images taken by the Galileo spacecraft during its flyby in 1993. These images provided the first direct confirmation of an asteroid moon.[36] At the time, it was separated from Ida by a distance of 90 kilometres (56 mi), moving in a prograde orbit. Dactyl is heavily cratered, like Ida, and consists of similar materials. Its origin is uncertain, but evidence from the flyby suggests that it originated as a fragment of the Koronis parent body.

Discovery edit

Dactyl was found on 17 February 1994 by Galileo mission member Ann Harch, while examining delayed image downloads from the spacecraft.[3] Galileo recorded 47 images of Dactyl over an observation period of 5.5 hours in August 1993.[77] The spacecraft was 10,760 kilometres (6,690 mi) from Ida[78] and 10,870 kilometres (6,750 mi) from Dactyl when the first image of the moon was captured, 14 minutes before Galileo made its closest approach.[79]

Dactyl was initially designated 1993 (243) 1.[78][80] It was named by the International Astronomical Union in 1994,[80] for the mythological dactyls who inhabited Mount Ida on the island of Crete.[81][82]

Physical characteristics edit

Dactyl is an "egg-shaped"[36] but "remarkably spherical"[81] object measuring 1.6 by 1.4 by 1.2 kilometres (0.99 by 0.87 by 0.75 mi).[36] It is oriented with its longest axis pointing towards Ida.[36] Like Ida, Dactyl's surface exhibits saturation cratering.[36] It is marked by more than a dozen craters with a diameter greater than 80 m (260 ft), indicating that the moon has suffered many collisions during its history.[16] At least six craters form a linear chain, suggesting that it was caused by locally produced debris, possibly ejected from Ida.[36] Dactyl's craters may contain central peaks, unlike those found on Ida.[83] These features, and Dactyl's spheroidal shape, imply that the moon is gravitationally controlled despite its small size.[83] Like Ida, its average temperature is about 200 K (−73 °C; −100 °F).[3]

Dactyl shares many characteristics with Ida. Their albedos and reflection spectra are very similar.[84] The small differences indicate that the space weathering process is less active on Dactyl.[39] Its small size would make the formation of significant amounts of regolith impossible.[39][78] This contrasts with Ida, which is covered by a deep layer of regolith.

The two largest imaged craters on Dactyl were named Acmon /ˈækmən/ and Celmis /ˈsɛlmɪs/, after two of the mythological dactyls. Acmon is the largest crater in the above image, and Celmis is near the bottom of the image, mostly obscured in shadow. The craters are 300 and 200 meters in diameter, respectively.[85]

Orbit edit

 
Diagram of potential orbits of Dactyl around Ida

Dactyl's orbit around Ida is not precisely known. Galileo was in the plane of Dactyl's orbit when most of the images were taken, which made determining its exact orbit difficult.[37] Dactyl orbits in the prograde direction[86] and is inclined about 8° to Ida's equator.[77] Based on computer simulations, Dactyl's pericenter must be more than about 65 km (40 mi) from Ida for it to remain in a stable orbit.[87] The range of orbits generated by the simulations was narrowed down by the necessity of having the orbits pass through points at which Galileo observed Dactyl to be at 16:52:05 UT on 28 August 1993, about 90 km (56 mi) from Ida at longitude 85°.[88][89] On 26 April 1994, the Hubble Space Telescope observed Ida for eight hours and was unable to spot Dactyl. It would have been able to observe it if it were more than about 700 km (430 mi) from Ida.[37]

If in a circular orbit at the distance at which it was seen, Dactyl's orbital period would be about 20 hours.[84] Its orbital speed is roughly 10 m/s (33 ft/s), "about the speed of a fast run or a slowly thrown baseball".[37]

Age and origin edit

Dactyl may have originated at the same time as Ida,[90] from the disruption of the Koronis parent body.[53] However, it may have formed more recently, perhaps as ejecta from a large impact on Ida.[91] It is extremely unlikely that it was captured by Ida.[79] Dactyl may have suffered a major impact around 100 million years ago, which reduced its size.[72]

See also edit

Notes edit

  1. ^ a b Raab 2002
  2. ^ Noah Webster (1884) A Practical Dictionary of the English Language
  3. ^ a b c d e f g h Holm 1994
  4. ^ "Idæan". Oxford English Dictionary (Online ed.). Oxford University Press. (Subscription or participating institution membership required.)
  5. ^ a b c d e JPL 2008
  6. ^ Belton et al. 1996
  7. ^ a b Britt et al. 2002, p. 486
  8. ^ Belton, M. J. S.; Chapman, C. R.; Thomas, P. C.; Davies, M. E.; Greenberg, R.; Klaasen, K.; et al. (1995). "Bulk density of asteroid 243 Ida from the orbit of its satellite Dactyl". Nature. 374 (6525): 785–788. Bibcode:1995Natur.374..785B. doi:10.1038/374785a0. S2CID 4333634.
  9. ^ a b c d e Thomas et al. 1996
  10. ^ a b c Vokrouhlicky, Nesvorny & Bottke 2003, p. 147
  11. ^ a b c Seidelmann Archinal A'hearn et al. 2007, p. 171
  12. ^ a b c d Wilson, Keil & Love 1999, p. 479
  13. ^ Ridpath 1897, p. 206
  14. ^ Schmadel 2003, p. 36
  15. ^ Berger 2003, p. 241
  16. ^ a b c d NASA 2005
  17. ^ a b c Chapman 1996, p. 700
  18. ^ Zellner, Tholen & Tedesco 1985, pp. 357, 373
  19. ^ Zellner, Tholen & Tedesco 1985, p. 404

    The Eos and Koronis families ... are entirely of type S, which is rare at their heliocentric distances ...
  20. ^ Zellner, Tholen & Tedesco 1985, p. 410
  21. ^ Owen & Yeomans 1994, p. 2295
  22. ^ D'Amario, Bright & Wolf 1992, p. 26
  23. ^ a b c d Chapman 1996, p. 699
  24. ^ D'Amario, Bright & Wolf 1992, p. 24
  25. ^ D'Amario, Bright & Wolf 1992, p. 72
  26. ^ a b D'Amario, Bright & Wolf 1992, p. 36
  27. ^ Sullivan et al. 1996, p. 120
  28. ^ Cowen 1993, p. 215

    Nearly a month after a successful photo session, the Galileo spacecraft last week finished radioing to Earth a high-resolution portrait of the second asteroid ever to be imaged from space. Known as 243 Ida, the asteroid was photographed from an average distance of just 3,400 kilometers some 3.5 minutes before Galileo's closest approach on Aug. 28.
  29. ^ Chapman 1994, p. 358
  30. ^ a b c d e f g h i j k Chapman 1996, p. 707
  31. ^ a b Chapman et al. 1994, p. 237
  32. ^ a b Greeley et al. 1994, p. 469
  33. ^ Monet et al. 1994, p. 2293
  34. ^ Geissler, Petit & Greenberg 1996, p. 57
  35. ^ Chapman et al. 1994, p. 238
  36. ^ a b c d e f g h Chapman 1996, p. 709
  37. ^ a b c d e Byrnes & D'Amario 1994
  38. ^ a b c Chapman 1996, p. 710
  39. ^ a b c d e f g Chapman 1995, p. 496
  40. ^ Petit et al. 1997, pp. 179–180
  41. ^ Geissler et al. 1996, p. 142
  42. ^ Lee et al. 1996, p. 99
  43. ^ a b c d Geissler, Petit & Greenberg 1996, p. 58
  44. ^ a b c Chapman 1994, p. 363
  45. ^ a b c Bottke et al. 2002, p. 10
  46. ^ a b c Cowen 1995
  47. ^ Lee et al. 1996, p. 96
  48. ^ Greeley et al. 1994, p. 470
  49. ^ Chapman 1996, p. 701
  50. ^ Lee et al. 1996, p. 90
  51. ^ a b Geissler et al. 1996, p. 141
  52. ^ a b Sullivan et al. 1996, p. 132
  53. ^ a b c Lee et al. 1996, p. 97
  54. ^ a b Stooke 1997, p. 1385
  55. ^ Sárneczky & Kereszturi 2002
  56. ^ Sullivan et al. 1996, p. 131
  57. ^ a b Thomas & Prockter 2004
  58. ^ Geissler, Petit & Greenberg 1996, pp. 57–58
  59. ^ Chapman 1996, pp. 707–708
  60. ^ a b USGS
  61. ^ Greeley & Batson 2001, p. 393
  62. ^ Bottke et al. 2002, p. 9
  63. ^ a b Sullivan et al. 1996, p. 124
  64. ^ Sullivan et al. 1996, p. 128
  65. ^ Geissler et al. 1996, p. 155
  66. ^ a b Wilson, Keil & Love 1999, p. 480
  67. ^ Lewis 1996, p. 89

    The chondrites fall naturally into five composition classes, of which three have very similar mineral contents, but different proportions of metal and silicates. All three contain abundant iron in three different forms (ferrous iron oxide in silicates, metallic iron, and ferrous sulfide), usually with all three abundant enough to be classified as potential ores. All three contain feldspar (an aluminosilicate of calcium, sodium, and potassium), pyroxene (silicates with one silicon atom for each atom of magnesium, iron, or calcium), olivine (silicates with two iron or magnesium atoms per silicon atom), metallic iron, and iron sulfide (the mineral troilite). These three classes, referred to collectively as the ordinary chondrites, contain quite different amounts of metal.
  68. ^ Thomas & Prockter 2004, p. 21
  69. ^ a b Sullivan et al. 1996, p. 135
  70. ^ Greenberg et al. 1996, p. 107
  71. ^ Slivan 1995, p. 134
  72. ^ a b c d Greenberg et al. 1996, p. 117
  73. ^ Hurford & Greenberg 2000, p. 1595
  74. ^ Carroll & Ostlie 1996, p. 878
  75. ^ "dactyl". Oxford English Dictionary (Online ed.). Oxford University Press. (Subscription or participating institution membership required.)
  76. ^ Edward Coleridge (1990) "The Argonautica" of Apollonius Rhodius, p. 42
  77. ^ a b c Petit et al. 1997, p. 177
  78. ^ a b c Belton & Carlson 1994
  79. ^ a b Mason 1994, p. 108
  80. ^ a b Green 1994
  81. ^ a b Schmadel 2003, p. 37
  82. ^ Pausanias & 5.7.6

    When Zeus was born, Rhea entrusted the guardianship of her son to the Dactyls of Ida, who are the same as those called Curetes. They came from Cretan Ida – Heracles, Paeonaeus, Epimedes, Iasius and Idas.
  83. ^ a b Asphaug, Ryan & Zuber 2003, p. 463
  84. ^ a b Chapman et al. 1994, p. 455
  85. ^ . IAU. Archived from the original on 1 July 2015. Retrieved 18 July 2015.
  86. ^ Petit et al. 1997, p. 179
  87. ^ Petit et al. 1997, p. 195
  88. ^ Petit et al. 1997, p. 188
  89. ^ Petit et al. 1997, p. 193
  90. ^ Greenberg et al. 1996, p. 116
  91. ^ Petit et al. 1997, p. 182

References edit

Journal articles edit

  • Asphaug, Erik; Ryan, Eileen V.; Zuber, Maria T. (2003). "Asteroid Interiors" (PDF). Asteroids III: 463–484. Bibcode:2002aste.book..463A. Retrieved 4 January 2009.
  • Bottke, William F. Jr.; Cellino, A.; Paolicchi, P.; Binzel, R. P. (2002). "An Overview of the Asteroids: The Asteroids III Perspective" (PDF). Asteroids III: 3–15. Bibcode:2002aste.book....3B. doi:10.2307/j.ctv1v7zdn4.7. Retrieved 23 October 2008.
  • Belton, M. J. S.; Chapman, Clark R.; Klaasen, Kenneth P.; Harch, Ann P.; Thomas, Peter C.; Veverka, Joseph; McEwen, Alfred S.; Pappalardo, Robert T. (1996). "Galileo's Encounter with 243 Ida: An Overview of the Imaging Experiment". Icarus. 120 (1): 1–19. Bibcode:1996Icar..120....1B. doi:10.1006/icar.1996.0032. S2CID 51885221.
  • Britt, D. T.; Yeomans, D. K.; Housen, K.; Consolmagno, G. (2002). "Asteroid Density, Porosity, and Structure" (PDF). Asteroids III: 485–500. Bibcode:2002aste.book..485B. doi:10.2307/j.ctv1v7zdn4.37. (PDF) from the original on 17 September 2003. Retrieved 27 October 2008.
  • Chapman, Clark R. (1994). "The Galileo Encounters with Gaspra and Ida". Asteroids, Comets, Meteors. 160: 357–365. Bibcode:1994IAUS..160..357C.
  • Chapman, Clark R.; Klaasen, K.; Belton, Michael J. S.; Veverka, Joseph (July 1994). "Asteroid 243 IDA and its satellite". Meteoritics. 29: 455. Bibcode:1994Metic..29..455C.
  • Chapman, Clark R. (September 1995). "Galileo Observations of Gaspra, Ida, and Dactyl: Implications for Meteoritics". Meteoritics. 30 (5): 496. Bibcode:1995Metic..30R.496C.
  • Chapman, Clark R. (October 1996). "S-Type Asteroids, Ordinary Chondrites, and Space Weathering: The Evidence from Galileo's Fly-bys of Gaspra and Ida". Meteoritics. 31 (6): 699–725. Bibcode:1996M&PS...31..699C. doi:10.1111/j.1945-5100.1996.tb02107.x.
  • Chapman, Clark R.; Ryan, Eileen V.; Merline, William J.; Neukum, Gerhard; Wagner, Roland; Thomas, Peter C.; Veverka, Joseph; Sullivan, Robert J. (March 1996). "Cratering on Ida". Icarus. 120 (1): 77–86. Bibcode:1996Icar..120...77C. doi:10.1006/icar.1996.0038. Retrieved 27 October 2008.
  • D'Amario, Louis A.; Bright, Larry E.; Wolf, Aron A. (May 1992). "Galileo trajectory design". Space Science Reviews. 60 (1–4): 23–78. Bibcode:1992SSRv...60...23D. doi:10.1007/BF00216849. S2CID 122388506.
  • Geissler, Paul E.; Petit, Jean-Marc; Durda, Daniel D.; Greenberg, Richard; Bottke, William F.; Nolan, Michael; Moore, Jeffrey (March 1996). "Erosion and Ejecta Reaccretion on 243 Ida and Its Moon" (PDF). Icarus. 120 (1): 140–157. Bibcode:1996Icar..120..140G. doi:10.1006/icar.1996.0042. (PDF) from the original on 20 March 2009. Retrieved 26 March 2009.
  • Geissler, Paul E.; Petit, Jean-Marc; Greenberg, Richard (1996). "Ejecta Reaccretion on Rapidly Rotating Asteroids: Implications for 243 Ida and 433 Eros". Completing the Inventory of the Solar System. 107: 57–67. Bibcode:1996ASPC..107...57G.
  • Greenberg, Richard; Bottke, William F.; Nolan, Michael; Geissler, Paul E.; Petit, Jean-Marc; Durda, Daniel D.; Asphaug, Erik; Head, James (March 1996). "Collisional and Dynamical History of Ida" (PDF). Icarus. 120 (1): 106–118. Bibcode:1996Icar..120..106G. doi:10.1006/icar.1996.0040. Retrieved 23 October 2008.
  • Hurford, Terry A.; Greenberg, Richard (June 2000). "Tidal Evolution by Elongated Primaries: Implications for the Ida/Dactyl System". Geophysical Research Letters. 27 (11): 1595–1598. Bibcode:2000GeoRL..27.1595H. doi:10.1029/1999GL010956.
  • Lee, Pascal; Veverka, Joseph; Thomas, Peter C.; Helfenstein, Paul; Belton, Michael J. S.; Chapman, Clark R.; Greeley, Ronald; Pappalardo, Robert T.; et al. (March 1996). (PDF). Icarus. 120 (1): 87–105. Bibcode:1996Icar..120...87L. doi:10.1006/icar.1996.0039. Archived from the original (PDF) on 12 June 2016. Retrieved 27 October 2008.
  • Mason, John W. (June 1994). "Ida's new moon". Journal of the British Astronomical Association. 104 (3): 108. Bibcode:1994JBAA..104..108M.
  • Monet, A. K. B.; Stone, R. C.; Monet, D. G.; Dahn, C. C.; Harris, H. C.; Leggett, S. K.; Pier, J. R.; Vrba, F. J.; Walker, R. L. (June 1994). "Astrometry for the Galileo mission. 1: Asteroid encounters". The Astronomical Journal. 107 (6): 2290–2294. Bibcode:1994AJ....107.2290M. doi:10.1086/117036.
  • Owen, W. M. Jr.; Yeomans, D. K. (June 1994). "The overlapping plates method applied to CCD observations of 243 Ida". The Astronomical Journal. 107 (6): 2295–2298. Bibcode:1994AJ....107.2295O. doi:10.1086/117037.
  • Petit, Jean-Marc; Durda, Daniel D.; Greenberg, Richard; Hurford, Terry A.; Geissler, Paul E. (November 1997). "The Long-Term Dynamics of Dactyl's Orbit". Icarus. 130 (1): 177–197. Bibcode:1997Icar..130..177P. CiteSeerX 10.1.1.693.8814. doi:10.1006/icar.1997.5788.
  • Seidelmann, P. Kenneth; Archinal, Brent A.; A'Hearn, Michael F.; et al. (2007). "Report of the IAU/IAG Working Group on cartographic coordinates and rotational elements: 2006". Celestial Mechanics and Dynamical Astronomy. 98 (3): 155–180. Bibcode:2007CeMDA..98..155S. doi:10.1007/s10569-007-9072-y.
  • Sullivan, Robert J.; Greeley, Ronald; Pappalardo, R.; Asphaug, E.; Moore, J. M.; Morrison, D.; Belton, Michael J. S.; Carr, M.; et al. (March 1996). (PDF). Icarus. 120 (1): 119–139. Bibcode:1996Icar..120..119S. doi:10.1006/icar.1996.0041. Archived from the original (PDF) on 12 June 2016. Retrieved 27 October 2008.
  • Thomas, Peter C.; Belton, Michael J. S.; Carcich, B.; Chapman, Clark R.; Davies, M. E.; Sullivan, Robert J.; Veverka, Joseph (1996). "The shape of Ida". Icarus. 120 (1): 20–32. Bibcode:1996Icar..120...20T. doi:10.1006/icar.1996.0033.
  • Vokrouhlicky, David; Nesvorny, David; Bottke, William F. (11 September 2003). "The vector alignments of asteroid spins by thermal torques" (PDF). Nature. 425 (6954): 147–151. Bibcode:2003Natur.425..147V. doi:10.1038/nature01948. PMID 12968171. S2CID 4367378. (PDF) from the original on 11 May 2008. Retrieved 23 October 2008.
  • Wilson, Lionel; Keil, Klaus; Love, Stanley J. (May 1999). "The internal structures and densities of asteroids". Meteoritics & Planetary Science. 34 (3): 479–483. Bibcode:1999M&PS...34..479W. doi:10.1111/j.1945-5100.1999.tb01355.x. S2CID 129231326.
  • Zellner, Ben; Tholen, David J.; Tedesco, Edward F. (March 1985). "The eight-color asteroid survey: Results for 589 minor planets". Icarus. 61 (3): 355–416. Bibcode:1985Icar...61..355Z. doi:10.1016/0019-1035(85)90133-2.

Books edit

  • Berger, Peter (2003). "The Gildemeester Organisation for Assistance to Emigrants and the expulsion of Jews from Vienna, 1938–1942". In Gourvish, Terry (ed.). Business and Politics in Europe, 1900–1970. Cambridge, UK: Cambridge University Press. ISBN 978-0-521-82344-9.
  • Carroll, Bradley W.; Ostlie, Dale A. (1996). An Introduction to Modern Astrophysics. Addison-Wesley Publishing Company. ISBN 978-0-201-54730-6.
  • Greeley, Ronald; Batson, Raymond M. (2001). The Compact NASA Atlas of the Solar System. Cambridge, UK: Cambridge University Press. ISBN 978-0-521-80633-6.
  • Lewis, John S. (1996). Mining the Sky: Untold Riches from the Asteroids, Comets, and Planets. Reading, MA: Addison-Wesley. ISBN 978-0-201-47959-1.
  • Pausanias (1916). Description of Greece. Translated by Jones, W. H. S.; Omerod, H. A. Loeb Classical Library. ISBN 978-0-674-99104-0.
  • Ridpath, John Clark (1897). The Standard American Encyclopedia of Arts, Sciences, History, Biography, Geography, Statistics, and General Knowledge. Encyclopedia Publishing.
  • Schmadel, Lutz D. (2003). "Catalogue of Minor Planet Names and Discovery Circumstances". Dictionary of minor planet names. IAU commission. Vol. 20. Springer. ISBN 978-3-540-00238-3.
  • Slivan, Stephen Michael (June 1995). Spin-Axis Alignment of Koronis Family Asteroids (Thesis). Massachusetts Institute of Technology. hdl:1721.1/11867. OCLC 32907677.
  • Thomas, Peter C.; Prockter, Louise M. (28 May 2004). (PDF). Planetary Tectonics. Cambridge Planetary Science. Vol. 11. Cambridge University Press. ISBN 978-0-521-76573-2. Archived from the original (PDF) on 4 March 2009. Retrieved 29 November 2008.

Other edit

  • Belton, Michael J. S.; Carlson, R. (12 March 1994). "1993 (243) 1". IAU Circular. 5948 (5948): 2. Bibcode:1994IAUC.5948....2B.
  • Byrnes, Dennis V.; D'Amario, Louis A.; Galileo Navigation Team (December 1994). . The Galileo Messenger (35). Archived from the original on 5 January 1997. Retrieved 23 October 2008.
  • Chapman, Clark R.; Belton, Michael J. S.; Veverka, Joseph; Neukum, G.; Head, J.; Greeley, Ronald; Klaasen, K.; Morrison, D. (March 1994). "First Galileo image of asteroid 243 Ida". Abstracts of the 25th Lunar and Planetary Science Conference: 237–238. Bibcode:1994LPI....25..237C.
  • Cowen, Ron (2 October 1993). "Close-up of an asteroid: Galileo eyes Ida". Science News. Vol. 144, no. 14. p. 215. ISSN 0036-8423.
  • Cowen, Ron (1 April 1995). (PDF). Science News. Vol. 147, no. 15. p. 207. ISSN 0036-8423. Archived from the original (PDF) on 27 March 2012. Retrieved 26 March 2009.
  • Greeley, Ronald; Sullivan, Robert J.; Pappalardo, R.; Head, J.; Veverka, Joseph; Thomas, Peter C.; Lee, P.; Belton, M.; Chapman, Clark R. (March 1994). "Morphology and Geology of Asteroid Ida: Preliminary Galileo Imaging Observations". Abstracts of the 25th Lunar and Planetary Science Conference: 469–470. Bibcode:1994LPI....25..469G.
  • Green, Daniel W. E. (26 September 1994). "1993 (243) 1 = (243) Ida I (Dactyl)". IAU Circular. 6082 (6082): 2. Bibcode:1994IAUC.6082....2G.
  • Holm, Jeanne (June 1994). Jones, Jan (ed.). . The Galileo Messenger (34). Archived from the original on 24 June 2010. Retrieved 23 October 2008. Alt URL
  • Raab, Herbert (2002). (PDF). Meeting on Asteroids and Comets in Europe. Archived from the original (PDF) on 30 October 2008. Retrieved 23 October 2008.
  • Sárneczky, K; Kereszturi, Á. (March 2002). "'Global' Tectonism on Asteroids?" (PDF). 33rd Annual Lunar and Planetary Science Conference: 1381. Bibcode:2002LPI....33.1381S. (PDF) from the original on 26 January 2005. Retrieved 22 October 2008.
  • Stooke, P. J. (1997). "Reflections on the Geology of 243 Ida" (PDF). Lunar and Planetary Science XXVIII: 1385–1386. Bibcode:1997LPI....28.1385S. (PDF) from the original on 4 March 2009. Retrieved 29 November 2008.
  • "JPL Small-Body Database Browser: 243 Ida". Jet Propulsion Laboratory. 25 August 2008.
  • . National Aeronautics and Space Administration. 23 August 2005. Archived from the original on 21 October 2008. Retrieved 4 December 2008.
  • "Gazetteer of Planetary Nomenclature: Ida". United States Geological Survey Astrogeology Research Program. Retrieved 15 April 2009.

External links edit

 
Wikimedia Commons has media related to (243) Ida.
  • Asteroids with Satellites, Robert Johnston, johnstonsarchive.net
  • 243 Ida at AstDyS-2, Asteroids—Dynamic Site
    • Ephemeris · Observation prediction · Orbital info · Proper elements · Observational info
  • 243 Ida at the JPL Small-Body Database  
    • Close approach · Discovery · Ephemeris · Orbit diagram · Orbital elements · Physical parameters

January 01, 1970
this, article, about, asteroid, other, uses, disambiguation, minor, planet, designation, asteroid, koronis, family, asteroid, belt, discovered, september, 1884, austrian, astronomer, johann, palisa, vienna, observatory, named, after, nymph, from, greek, mythol. This article is about an asteroid For other uses see Ida disambiguation Ida minor planet designation 243 Ida is an asteroid in the Koronis family of the asteroid belt It was discovered on 29 September 1884 by Austrian astronomer Johann Palisa at Vienna Observatory and named after a nymph from Greek mythology Later telescopic observations categorized Ida as an S type asteroid the most numerous type in the inner asteroid belt On 28 August 1993 Ida was visited by the uncrewed Galileo spacecraft while en route to Jupiter It was the second asteroid visited by a spacecraft and the first found to have a natural satellite IdaGalileo image of 243 Ida The dot to the right is its moon Dactyl Discovery 1 Discovered byJohann PalisaDiscovery siteVienna ObservatoryDiscovery dateSeptember 29 1884DesignationsMPC designation 243 IdaPronunciation ˈ aɪ d e 2 Named afterIda nurse of Zeus Minor planet categoryMain belt Koronis family 3 AdjectivesIdean Idaean aɪ ˈ d iː e n 4 Orbital characteristics 5 Epoch 31 July 2016 JD 2457600 5 Aphelion2 979 AU 4 457 1011 m Perihelion2 743 AU 4 103 1011 m Semi major axis2 861 AU 4 280 1011 m Eccentricity0 0411Orbital period sidereal 1 767 644 days 4 83955 a Average orbital speed0 2036 dMean anomaly38 707 Inclination1 132 Longitude of ascending node324 016 Argument of perihelion110 961 Known satellitesDactylPhysical characteristicsDimensions59 8 25 4 18 6 km 6 Mean radius15 7 km 7 Mass4 2 0 6 1016 kg 7 Mean density2 6 0 5 g cm3 8 Equatorial surface gravity0 3 1 1 cm s2 9 Synodic rotation period4 63 hours 0 193 d 10 North pole right ascension168 76 11 North pole declination 2 88 11 Geometric albedo0 2383 5 Temperature200 K 73 C 3 Spectral typeS 12 Absolute magnitude H 9 94 5 Ida s orbit lies between the planets Mars and Jupiter like all main belt asteroids Its orbital period is 4 84 years and its rotation period is 4 63 hours Ida has an average diameter of 31 4 km 19 5 mi It is irregularly shaped and elongated apparently composed of two large objects connected together Its surface is one of the most heavily cratered in the Solar System featuring a wide variety of crater sizes and ages Ida s moon Dactyl was discovered by mission member Ann Harch in images returned from Galileo It was named after the Dactyls creatures which inhabited Mount Ida in Greek mythology Dactyl is only 1 4 kilometres 0 87 mi in diameter about 1 20 the size of Ida Its orbit around Ida could not be determined with much accuracy but the constraints of possible orbits allowed a rough determination of Ida s density and revealed that it is depleted of metallic minerals Dactyl and Ida share many characteristics suggesting a common origin The images returned from Galileo and the subsequent measurement of Ida s mass provided new insights into the geology of S type asteroids Before the Galileo flyby many different theories had been proposed to explain their mineral composition Determining their composition permits a correlation between meteorites falling to the Earth and their origin in the asteroid belt Data returned from the flyby pointed to S type asteroids as the source for the ordinary chondrite meteorites the most common type found on the Earth s surface Contents 1 Discovery and observations 2 Exploration 2 1 Galileo flyby 2 2 Discoveries 3 Physical characteristics 4 Surface features 4 1 Regolith 4 2 Structures 4 3 Craters 5 Composition 6 Orbit and rotation 7 Origin 8 Dactyl 8 1 Discovery 8 2 Physical characteristics 8 3 Orbit 8 4 Age and origin 9 See also 10 Notes 11 References 11 1 Journal articles 11 2 Books 11 3 Other 12 External linksDiscovery and observations editIda was discovered on 29 September 1884 by Austrian astronomer Johann Palisa at the Vienna Observatory 13 It was his 45th asteroid discovery 1 Ida was named by Moriz von Kuffner a Viennese brewer and amateur astronomer 14 15 In Greek mythology Ida was a nymph of Crete who raised the god Zeus 16 Ida was recognized as a member of the Koronis family by Kiyotsugu Hirayama who proposed in 1918 that the group comprised the remnants of a destroyed precursor body 17 Ida s reflection spectrum was measured on 16 September 1980 by astronomers David J Tholen and Edward F Tedesco as part of the eight color asteroid survey ECAS 18 Its spectrum matched those of the asteroids in the S type classification 19 20 Many observations of Ida were made in early 1993 by the US Naval Observatory in Flagstaff and the Oak Ridge Observatory These improved the measurement of Ida s orbit around the Sun and reduced the uncertainty of its position during the Galileo flyby from 78 to 60 km 48 to 37 mi 21 Exploration edit nbsp Animation of Galileo s trajectory from 19 October 1989 to 30 September 2003 Galileo Jupiter Earth Venus 951 Gaspra 243 Ida nbsp Trajectory of Galileo from launch to Jupiter orbital insertion Galileo flyby edit Ida was visited in 1993 by the Jupiter bound space probe Galileo Its encounters of the asteroids Gaspra and Ida were secondary to the Jupiter mission These were selected as targets in response to a new NASA policy directing mission planners to consider asteroid flybys for all spacecraft crossing the belt 22 No prior missions had attempted such a flyby 23 Galileo was launched into orbit by the Space Shuttle Atlantis mission STS 34 on 18 October 1989 24 Changing Galileo s trajectory to approach Ida required that it consume 34 kg 75 lb of propellant 25 Mission planners delayed the decision to attempt a flyby until they were certain that this would leave the spacecraft enough propellant to complete its Jupiter mission 26 nbsp Images from the flyby starting 5 4 hours before closest approach and showing Ida s rotation Galileo s trajectory carried it into the asteroid belt twice on its way to Jupiter During its second crossing it flew by Ida on 28 August 1993 at a speed of 12 400 m s 41 000 ft s relative to the asteroid 26 The onboard imager observed Ida from a distance of 240 350 km 149 350 mi to its closest approach of 2 390 km 1 490 mi 16 27 Ida was the second asteroid after Gaspra to be imaged by a spacecraft 28 About 95 of Ida s surface came into view of the probe during the flyby 9 Transmission of many Ida images was delayed due to a permanent failure in the spacecraft s high gain antenna 29 The first five images were received in September 1993 30 These comprised a high resolution mosaic of the asteroid at a resolution of 31 38 m pixel 31 32 The remaining images were sent in February 1994 3 when the spacecraft s proximity to the Earth allowed higher speed transmissions 30 33 Discoveries edit The data returned from the Galileo flybys of Gaspra and Ida and the later NEAR Shoemaker asteroid mission permitted the first study of asteroid geology 34 Ida s relatively large surface exhibited a diverse range of geological features 35 The discovery of Ida s moon Dactyl the first confirmed satellite of an asteroid provided additional insights into Ida s composition 36 Ida is classified as an S type asteroid based on ground based spectroscopic measurements 37 The composition of S types was uncertain before the Galileo flybys but was interpreted to be either of two minerals found in meteorites that had fallen to the Earth ordinary chondrite OC and stony iron 12 Estimates of Ida s density are constrained to less than 3 2 g cm3 by the long term stability of Dactyl s orbit 37 This all but rules out a stony iron composition were Ida made of 5 g cm3 iron and nickel rich material it would have to contain more than 40 empty space 36 The Galileo images also led to the discovery that space weathering was taking place on Ida a process which causes older regions to become more red in color over time 17 38 The same process affects both Ida and its moon although Dactyl shows a lesser change 39 The weathering of Ida s surface revealed another detail about its composition the reflection spectra of freshly exposed parts of the surface resembled that of OC meteorites but the older regions matched the spectra of S type asteroids 23 nbsp Polished section of an ordinary chondrite meteorite Both of these discoveries the space weathering effects and the low density led to a new understanding about the relationship between S type asteroids and OC meteorites S types are the most numerous kind of asteroid in the inner part of the asteroid belt 23 OC meteorites are likewise the most common type of meteorite found on the Earth s surface 23 The reflection spectra measured by remote observations of S type asteroids however did not match that of OC meteorites The Galileo flyby of Ida found that some S types particularly the Koronis family could be the source of these meteorites 39 Physical characteristics edit nbsp Size comparison of Ida several other asteroids the dwarf planet Ceres and Mars Ida s mass is between 3 65 and 4 99 1016 kg 40 Its gravitational field produces an acceleration of about 0 3 to 1 1 cm s2 over its surface 9 This field is so weak that an astronaut standing on its surface could leap from one end of Ida to the other and an object moving in excess of 20 m s 70 ft s could escape the asteroid entirely 41 42 nbsp Successive images of a rotating Ida Ida is a distinctly elongated asteroid 43 with an irregular surface 44 45 Ida is 2 35 times as long as it is wide 43 and a waist separates it into two geologically dissimilar halves 30 This constricted shape is consistent with Ida being made of two large solid components with loose debris filling the gap between them However no such debris was seen in high resolution images captured by Galileo 45 Although there are a few steep slopes tilting up to about 50 on Ida the slope generally does not exceed 35 9 Ida s irregular shape is responsible for the asteroid s very uneven gravitational field 46 The surface acceleration is lowest at the extremities because of their high rotational speed It is also low near the waist because the mass of the asteroid is concentrated in the two halves away from this location 9 Surface features edit nbsp Mosaic of images recorded by Galileo 3 5 minutes before its closest approach Ida s surface appears heavily cratered and mostly gray although minor color variations mark newly formed or uncovered areas 16 Besides craters other features are evident such as grooves ridges and protrusions Ida is covered by a thick layer of regolith loose debris that obscures the solid rock beneath The largest boulder sized debris fragments are called ejecta blocks several of which have been observed on the surface Regolith edit The surface of Ida is covered in a blanket of pulverized rock called regolith about 50 100 m 160 330 ft thick 30 This material is produced in impact events and redistributed across Ida s surface by geological processes 47 Galileo observed evidence of recent downslope regolith movement 48 Ida s regolith is composed of the silicate minerals olivine and pyroxene 3 49 Its appearance changes over time through a process called space weathering 39 Because of this process older regolith appears more red in color compared to freshly exposed material 38 nbsp Galileo image of a 150 m 490 ft block at 24 8 S 2 8 E 50 About 20 large 40 150 m across ejecta blocks have been identified embedded in Ida s regolith 30 51 Ejecta blocks constitute the largest pieces of the regolith 52 Because ejecta blocks are expected to break down quickly by impact events those present on the surface must have been either formed recently or uncovered by an impact event 46 53 Most of them are located within the craters Lascaux and Mammoth but they may not have been produced there 53 This area attracts debris due to Ida s irregular gravitational field 46 Some blocks may have been ejected from the young crater Azzurra on the opposite side of the asteroid 54 Structures edit Several major structures mark Ida s surface The asteroid appears to be split into two halves here referred to as region 1 and region 2 connected by a waist 30 This feature may have been filled in by debris or blasted out of the asteroid by impacts 30 54 Region 1 of Ida contains two major structures One is a prominent 40 km 25 mi ridge named Townsend Dorsum that stretches 150 degrees around Ida s surface 55 The other structure is a large indentation named Vienna Regio 30 Ida s region 2 features several sets of grooves most of which are 100 m 330 ft wide or less and up to 4 km 2 5 mi long 30 56 They are located near but are not connected with the craters Mammoth Lascaux and Kartchner 52 Some grooves are related to major impact events for example a set opposite Vienna Regio 57 Craters edit Ida is one of the most densely cratered bodies yet explored in the Solar System 31 44 and impacts have been the primary process shaping its surface 58 Cratering has reached the saturation point meaning that new impacts erase evidence of old ones leaving the total crater count roughly the same 59 It is covered with craters of all sizes and stages of degradation 44 and ranging in age from fresh to as old as Ida itself 30 The oldest may have been formed during the breakup of the Koronis family parent body 39 The largest crater Lascaux is almost 12 km 7 5 mi across 45 60 Region 2 contains nearly all of the craters larger than 6 km 3 7 mi in diameter but Region 1 has no large craters at all 30 Some craters are arranged in chains 32 nbsp Asymmetric 1 5 km 0 93 mi wide crater Fingal at 13 2 S 39 9 E 60 Ida s major craters are named after caves and lava tubes on Earth The crater Azzurra for example is named after a submerged cave on the island of Capri also known as the Blue Grotto 61 Azzurra seems to be the most recent major impact on Ida 51 The ejecta from this collision is distributed discontinuously over Ida 38 and is responsible for the large scale color and albedo variations across its surface 62 An exception to the crater morphology is the fresh asymmetric Fingal which has a sharp boundary between the floor and wall on one side 63 Another significant crater is Afon which marks Ida s prime meridian 11 The craters are simple in structure bowl shaped with no flat bottoms and no central peaks 63 They are distributed evenly around Ida except for a protrusion north of crater Choukoutien which is smoother and less cratered 64 The ejecta excavated by impacts is deposited differently on Ida than on planets because of its rapid rotation low gravity and irregular shape 43 Ejecta blankets settle asymmetrically around their craters but fast moving ejecta that escapes from the asteroid is permanently lost 65 Composition editIda was classified as an S type asteroid based on the similarity of its reflectance spectra with similar asteroids 12 S types may share their composition with stony iron or ordinary chondrite OC meteorites 12 The composition of the interior has not been directly analyzed but is assumed to be similar to OC material based on observed surface color changes and Ida s bulk density of 2 27 3 10 g cm3 39 66 OC meteorites contain varying amounts of the silicates olivine and pyroxene iron and feldspar 67 Olivine and pyroxene were detected on Ida by Galileo 3 The mineral content appears to be homogeneous throughout its extent Galileo found minimal variations on the surface and the asteroid s spin indicates a consistent density 68 69 Assuming that its composition is similar to OC meteorites which range in density from 3 48 to 3 64 g cm3 Ida would have a porosity of 11 42 66 Ida s interior probably contains some amount of impact fractured rock called megaregolith The megaregolith layer of Ida extends between hundreds of meters below the surface to a few kilometers Some rock in Ida s core may have been fractured below the large craters Mammoth Lascaux and Undara 69 Orbit and rotation edit nbsp Orbit and positions of Ida and five planets as of 9 March 2009 Ida is a member of the Koronis family of asteroid belt asteroids 17 Ida orbits the Sun at an average distance of 2 862 AU 428 1 Gm between the orbits of Mars and Jupiter 3 5 Ida takes 4 84089 years to complete one orbit 5 Ida s rotation period is 4 63 hours roughly 5 hours 10 43 making it one of the fastest rotating asteroids yet discovered 70 The calculated maximum moment of inertia of a uniformly dense object the same shape as Ida coincides with the spin axis of the asteroid This suggests that there are no major variations of density within the asteroid 57 Ida s axis of rotation precesses with a period of 77 thousand years due to the gravity of the Sun acting upon the nonspherical shape of the asteroid 71 Origin editIda originated in the breakup of the roughly 120 km 75 mi diameter Koronis parent body 10 The progenitor asteroid had partially differentiated with heavier metals migrating to the core 72 Ida carried away insignificant amounts of this core material 72 It is uncertain how long ago the disruption event occurred According to an analysis of Ida s cratering processes its surface is more than a billion years old 72 However this is inconsistent with the estimated age of the Ida Dactyl system of less than 100 million years 73 it is unlikely that Dactyl due to its small size could have escaped being destroyed in a major collision for longer The difference in age estimates may be explained by an increased rate of cratering from the debris of the Koronis parent body s destruction 74 Dactyl editDactyl nbsp Highest resolution image of Dactyl recorded while Galileo was about 3 900 km away from the moonDiscoveryDiscovered byAnn HarchDiscovery siteGalileo spacecraftDiscovery date17 February 1994DesignationsMPC designation 243 Ida I DactylPronunciation ˈ d ae k t ɪ l DAK til 75 Named afterDactylsAlternative designations1993 243 1AdjectivesDactylian d ae k ˈ t ɪ l i e n 76 Orbital characteristicsSemi major axis90 km at time of discoveryOrbital period sidereal prograde ca 20 hInclinationca 8 77 Satellite ofIdaPhysical characteristicsDimensions1 6 1 4 1 2 kmSynodic rotation periodsynchronousTemperature200 K 73 C 100 F Main article Dactyl moon Ida has a moon named Dactyl official designation 243 Ida I Dactyl It was discovered in images taken by the Galileo spacecraft during its flyby in 1993 These images provided the first direct confirmation of an asteroid moon 36 At the time it was separated from Ida by a distance of 90 kilometres 56 mi moving in a prograde orbit Dactyl is heavily cratered like Ida and consists of similar materials Its origin is uncertain but evidence from the flyby suggests that it originated as a fragment of the Koronis parent body Discovery edit Dactyl was found on 17 February 1994 by Galileo mission member Ann Harch while examining delayed image downloads from the spacecraft 3 Galileo recorded 47 images of Dactyl over an observation period of 5 5 hours in August 1993 77 The spacecraft was 10 760 kilometres 6 690 mi from Ida 78 and 10 870 kilometres 6 750 mi from Dactyl when the first image of the moon was captured 14 minutes before Galileo made its closest approach 79 Dactyl was initially designated 1993 243 1 78 80 It was named by the International Astronomical Union in 1994 80 for the mythological dactyls who inhabited Mount Ida on the island of Crete 81 82 Physical characteristics edit Dactyl is an egg shaped 36 but remarkably spherical 81 object measuring 1 6 by 1 4 by 1 2 kilometres 0 99 by 0 87 by 0 75 mi 36 It is oriented with its longest axis pointing towards Ida 36 Like Ida Dactyl s surface exhibits saturation cratering 36 It is marked by more than a dozen craters with a diameter greater than 80 m 260 ft indicating that the moon has suffered many collisions during its history 16 At least six craters form a linear chain suggesting that it was caused by locally produced debris possibly ejected from Ida 36 Dactyl s craters may contain central peaks unlike those found on Ida 83 These features and Dactyl s spheroidal shape imply that the moon is gravitationally controlled despite its small size 83 Like Ida its average temperature is about 200 K 73 C 100 F 3 Dactyl shares many characteristics with Ida Their albedos and reflection spectra are very similar 84 The small differences indicate that the space weathering process is less active on Dactyl 39 Its small size would make the formation of significant amounts of regolith impossible 39 78 This contrasts with Ida which is covered by a deep layer of regolith The two largest imaged craters on Dactyl were named Acmon ˈ ae k m e n and Celmis ˈ s ɛ l m ɪ s after two of the mythological dactyls Acmon is the largest crater in the above image and Celmis is near the bottom of the image mostly obscured in shadow The craters are 300 and 200 meters in diameter respectively 85 Orbit edit nbsp Diagram of potential orbits of Dactyl around Ida Dactyl s orbit around Ida is not precisely known Galileo was in the plane of Dactyl s orbit when most of the images were taken which made determining its exact orbit difficult 37 Dactyl orbits in the prograde direction 86 and is inclined about 8 to Ida s equator 77 Based on computer simulations Dactyl s pericenter must be more than about 65 km 40 mi from Ida for it to remain in a stable orbit 87 The range of orbits generated by the simulations was narrowed down by the necessity of having the orbits pass through points at which Galileo observed Dactyl to be at 16 52 05 UT on 28 August 1993 about 90 km 56 mi from Ida at longitude 85 88 89 On 26 April 1994 the Hubble Space Telescope observed Ida for eight hours and was unable to spot Dactyl It would have been able to observe it if it were more than about 700 km 430 mi from Ida 37 If in a circular orbit at the distance at which it was seen Dactyl s orbital period would be about 20 hours 84 Its orbital speed is roughly 10 m s 33 ft s about the speed of a fast run or a slowly thrown baseball 37 Age and origin edit Dactyl may have originated at the same time as Ida 90 from the disruption of the Koronis parent body 53 However it may have formed more recently perhaps as ejecta from a large impact on Ida 91 It is extremely unlikely that it was captured by Ida 79 Dactyl may have suffered a major impact around 100 million years ago which reduced its size 72 See also editList of geological features on 243 Ida and Dactyl List of minor planetsNotes edit a b Raab 2002 Noah Webster 1884 A Practical Dictionary of the English Language a b c d e f g h Holm 1994 Idaean Oxford English Dictionary Online ed Oxford University Press Subscription or participating institution membership required a b c d e JPL 2008 Belton et al 1996 a b Britt et al 2002 p 486 Belton M J S Chapman C R Thomas P C Davies M E Greenberg R Klaasen K et al 1995 Bulk density of asteroid 243 Ida from the orbit of its satellite Dactyl Nature 374 6525 785 788 Bibcode 1995Natur 374 785B doi 10 1038 374785a0 S2CID 4333634 a b c d e Thomas et al 1996 a b c Vokrouhlicky Nesvorny amp Bottke 2003 p 147 a b c Seidelmann Archinal A hearn et al 2007 p 171 a b c d Wilson Keil amp Love 1999 p 479 Ridpath 1897 p 206 Schmadel 2003 p 36 Berger 2003 p 241 a b c d NASA 2005 a b c Chapman 1996 p 700 Zellner Tholen amp Tedesco 1985 pp 357 373 Zellner Tholen amp Tedesco 1985 p 404 The Eos and Koronis families are entirely of type S which is rare at their heliocentric distances Zellner Tholen amp Tedesco 1985 p 410 Owen amp Yeomans 1994 p 2295 D Amario Bright amp Wolf 1992 p 26 a b c d Chapman 1996 p 699 D Amario Bright amp Wolf 1992 p 24 D Amario Bright amp Wolf 1992 p 72 a b D Amario Bright amp Wolf 1992 p 36 Sullivan et al 1996 p 120 Cowen 1993 p 215 Nearly a month after a successful photo session the Galileo spacecraft last week finished radioing to Earth a high resolution portrait of the second asteroid ever to be imaged from space Known as 243 Ida the asteroid was photographed from an average distance of just 3 400 kilometers some 3 5 minutes before Galileo s closest approach on Aug 28 Chapman 1994 p 358 a b c d e f g h i j k Chapman 1996 p 707 a b Chapman et al 1994 p 237 a b Greeley et al 1994 p 469 Monet et al 1994 p 2293 Geissler Petit amp Greenberg 1996 p 57 Chapman et al 1994 p 238 a b c d e f g h Chapman 1996 p 709 a b c d e Byrnes amp D Amario 1994 a b c Chapman 1996 p 710 a b c d e f g Chapman 1995 p 496 Petit et al 1997 pp 179 180 Geissler et al 1996 p 142 Lee et al 1996 p 99 a b c d Geissler Petit amp Greenberg 1996 p 58 a b c Chapman 1994 p 363 a b c Bottke et al 2002 p 10 a b c Cowen 1995 Lee et al 1996 p 96 Greeley et al 1994 p 470 Chapman 1996 p 701 Lee et al 1996 p 90 a b Geissler et al 1996 p 141 a b Sullivan et al 1996 p 132 a b c Lee et al 1996 p 97 a b Stooke 1997 p 1385 Sarneczky amp Kereszturi 2002 Sullivan et al 1996 p 131 a b Thomas amp Prockter 2004 Geissler Petit amp Greenberg 1996 pp 57 58 Chapman 1996 pp 707 708 a b USGS Greeley amp Batson 2001 p 393 Bottke et al 2002 p 9 a b Sullivan et al 1996 p 124 Sullivan et al 1996 p 128 Geissler et al 1996 p 155 a b Wilson Keil amp Love 1999 p 480 Lewis 1996 p 89 The chondrites fall naturally into five composition classes of which three have very similar mineral contents but different proportions of metal and silicates All three contain abundant iron in three different forms ferrous iron oxide in silicates metallic iron and ferrous sulfide usually with all three abundant enough to be classified as potential ores All three contain feldspar an aluminosilicate of calcium sodium and potassium pyroxene silicates with one silicon atom for each atom of magnesium iron or calcium olivine silicates with two iron or magnesium atoms per silicon atom metallic iron and iron sulfide the mineral troilite These three classes referred to collectively as the ordinary chondrites contain quite different amounts of metal Thomas amp Prockter 2004 p 21 a b Sullivan et al 1996 p 135 Greenberg et al 1996 p 107 Slivan 1995 p 134 a b c d Greenberg et al 1996 p 117 Hurford amp Greenberg 2000 p 1595 Carroll amp Ostlie 1996 p 878 dactyl Oxford English Dictionary Online ed Oxford University Press Subscription or participating institution membership required Edward Coleridge 1990 The Argonautica of Apollonius Rhodius p 42 a b c Petit et al 1997 p 177 a b c Belton amp Carlson 1994 a b Mason 1994 p 108 a b Green 1994 a b Schmadel 2003 p 37 Pausanias amp 5 7 6 When Zeus was born Rhea entrusted the guardianship of her son to the Dactyls of Ida who are the same as those called Curetes They came from Cretan Ida Heracles Paeonaeus Epimedes Iasius and Idas a b Asphaug Ryan amp Zuber 2003 p 463 a b Chapman et al 1994 p 455 Planetary Names Dactyl IAU Archived from the original on 1 July 2015 Retrieved 18 July 2015 Petit et al 1997 p 179 Petit et al 1997 p 195 Petit et al 1997 p 188 Petit et al 1997 p 193 Greenberg et al 1996 p 116 Petit et al 1997 p 182References editJournal articles edit Asphaug Erik Ryan Eileen V Zuber Maria T 2003 Asteroid Interiors PDF Asteroids III 463 484 Bibcode 2002aste book 463A Retrieved 4 January 2009 Bottke William F Jr Cellino A Paolicchi P Binzel R P 2002 An Overview of the Asteroids The Asteroids III Perspective PDF Asteroids III 3 15 Bibcode 2002aste book 3B doi 10 2307 j ctv1v7zdn4 7 Retrieved 23 October 2008 Belton M J S Chapman Clark R Klaasen Kenneth P Harch Ann P Thomas Peter C Veverka Joseph McEwen Alfred S Pappalardo Robert T 1996 Galileo s Encounter with 243 Ida An Overview of the Imaging Experiment Icarus 120 1 1 19 Bibcode 1996Icar 120 1B doi 10 1006 icar 1996 0032 S2CID 51885221 Britt D T Yeomans D K Housen K Consolmagno G 2002 Asteroid Density Porosity and Structure PDF Asteroids III 485 500 Bibcode 2002aste book 485B doi 10 2307 j ctv1v7zdn4 37 Archived PDF from the original on 17 September 2003 Retrieved 27 October 2008 Chapman Clark R 1994 The Galileo Encounters with Gaspra and Ida Asteroids Comets Meteors 160 357 365 Bibcode 1994IAUS 160 357C Chapman Clark R Klaasen K Belton Michael J S Veverka Joseph July 1994 Asteroid 243 IDA and its satellite Meteoritics 29 455 Bibcode 1994Metic 29 455C Chapman Clark R September 1995 Galileo Observations of Gaspra Ida and Dactyl Implications for Meteoritics Meteoritics 30 5 496 Bibcode 1995Metic 30R 496C Chapman Clark R October 1996 S Type Asteroids Ordinary Chondrites and Space Weathering The Evidence from Galileo s Fly bys of Gaspra and Ida Meteoritics 31 6 699 725 Bibcode 1996M amp PS 31 699C doi 10 1111 j 1945 5100 1996 tb02107 x Chapman Clark R Ryan Eileen V Merline William J Neukum Gerhard Wagner Roland Thomas Peter C Veverka Joseph Sullivan Robert J March 1996 Cratering on Ida Icarus 120 1 77 86 Bibcode 1996Icar 120 77C doi 10 1006 icar 1996 0038 Retrieved 27 October 2008 D Amario Louis A Bright Larry E Wolf Aron A May 1992 Galileo trajectory design Space Science Reviews 60 1 4 23 78 Bibcode 1992SSRv 60 23D doi 10 1007 BF00216849 S2CID 122388506 Geissler Paul E Petit Jean Marc Durda Daniel D Greenberg Richard Bottke William F Nolan Michael Moore Jeffrey March 1996 Erosion and Ejecta Reaccretion on 243 Ida and Its Moon PDF Icarus 120 1 140 157 Bibcode 1996Icar 120 140G doi 10 1006 icar 1996 0042 Archived PDF from the original on 20 March 2009 Retrieved 26 March 2009 Geissler Paul E Petit Jean Marc Greenberg Richard 1996 Ejecta Reaccretion on Rapidly Rotating Asteroids Implications for 243 Ida and 433 Eros Completing the Inventory of the Solar System 107 57 67 Bibcode 1996ASPC 107 57G Greenberg Richard Bottke William F Nolan Michael Geissler Paul E Petit Jean Marc Durda Daniel D Asphaug Erik Head James March 1996 Collisional and Dynamical History of Ida PDF Icarus 120 1 106 118 Bibcode 1996Icar 120 106G doi 10 1006 icar 1996 0040 Retrieved 23 October 2008 Hurford Terry A Greenberg Richard June 2000 Tidal Evolution by Elongated Primaries Implications for the Ida Dactyl System Geophysical Research Letters 27 11 1595 1598 Bibcode 2000GeoRL 27 1595H doi 10 1029 1999GL010956 Lee Pascal Veverka Joseph Thomas Peter C Helfenstein Paul Belton Michael J S Chapman Clark R Greeley Ronald Pappalardo Robert T et al March 1996 Ejecta Blocks on 243 Ida and on Other Asteroids PDF Icarus 120 1 87 105 Bibcode 1996Icar 120 87L doi 10 1006 icar 1996 0039 Archived from the original PDF on 12 June 2016 Retrieved 27 October 2008 Mason John W June 1994 Ida s new moon Journal of the British Astronomical Association 104 3 108 Bibcode 1994JBAA 104 108M Monet A K B Stone R C Monet D G Dahn C C Harris H C Leggett S K Pier J R Vrba F J Walker R L June 1994 Astrometry for the Galileo mission 1 Asteroid encounters The Astronomical Journal 107 6 2290 2294 Bibcode 1994AJ 107 2290M doi 10 1086 117036 Owen W M Jr Yeomans D K June 1994 The overlapping plates method applied to CCD observations of 243 Ida The Astronomical Journal 107 6 2295 2298 Bibcode 1994AJ 107 2295O doi 10 1086 117037 Petit Jean Marc Durda Daniel D Greenberg Richard Hurford Terry A Geissler Paul E November 1997 The Long Term Dynamics of Dactyl s Orbit Icarus 130 1 177 197 Bibcode 1997Icar 130 177P CiteSeerX 10 1 1 693 8814 doi 10 1006 icar 1997 5788 Seidelmann P Kenneth Archinal Brent A A Hearn Michael F et al 2007 Report of the IAU IAG Working Group on cartographic coordinates and rotational elements 2006 Celestial Mechanics and Dynamical Astronomy 98 3 155 180 Bibcode 2007CeMDA 98 155S doi 10 1007 s10569 007 9072 y Sullivan Robert J Greeley Ronald Pappalardo R Asphaug E Moore J M Morrison D Belton Michael J S Carr M et al March 1996 Geology of 243 Ida PDF Icarus 120 1 119 139 Bibcode 1996Icar 120 119S doi 10 1006 icar 1996 0041 Archived from the original PDF on 12 June 2016 Retrieved 27 October 2008 Thomas Peter C Belton Michael J S Carcich B Chapman Clark R Davies M E Sullivan Robert J Veverka Joseph 1996 The shape of Ida Icarus 120 1 20 32 Bibcode 1996Icar 120 20T doi 10 1006 icar 1996 0033 Vokrouhlicky David Nesvorny David Bottke William F 11 September 2003 The vector alignments of asteroid spins by thermal torques PDF Nature 425 6954 147 151 Bibcode 2003Natur 425 147V doi 10 1038 nature01948 PMID 12968171 S2CID 4367378 Archived PDF from the original on 11 May 2008 Retrieved 23 October 2008 Wilson Lionel Keil Klaus Love Stanley J May 1999 The internal structures and densities of asteroids Meteoritics amp Planetary Science 34 3 479 483 Bibcode 1999M amp PS 34 479W doi 10 1111 j 1945 5100 1999 tb01355 x S2CID 129231326 Zellner Ben Tholen David J Tedesco Edward F March 1985 The eight color asteroid survey Results for 589 minor planets Icarus 61 3 355 416 Bibcode 1985Icar 61 355Z doi 10 1016 0019 1035 85 90133 2 Books edit Berger Peter 2003 The Gildemeester Organisation for Assistance to Emigrants and the expulsion of Jews from Vienna 1938 1942 In Gourvish Terry ed Business and Politics in Europe 1900 1970 Cambridge UK Cambridge University Press ISBN 978 0 521 82344 9 Carroll Bradley W Ostlie Dale A 1996 An Introduction to Modern Astrophysics Addison Wesley Publishing Company ISBN 978 0 201 54730 6 Greeley Ronald Batson Raymond M 2001 The Compact NASA Atlas of the Solar System Cambridge UK Cambridge University Press ISBN 978 0 521 80633 6 Lewis John S 1996 Mining the Sky Untold Riches from the Asteroids Comets and Planets Reading MA Addison Wesley ISBN 978 0 201 47959 1 Pausanias 1916 Description of Greece Translated by Jones W H S Omerod H A Loeb Classical Library ISBN 978 0 674 99104 0 Ridpath John Clark 1897 The Standard American Encyclopedia of Arts Sciences History Biography Geography Statistics and General Knowledge Encyclopedia Publishing Schmadel Lutz D 2003 Catalogue of Minor Planet Names and Discovery Circumstances Dictionary of minor planet names IAU commission Vol 20 Springer ISBN 978 3 540 00238 3 Slivan Stephen Michael June 1995 Spin Axis Alignment of Koronis Family Asteroids Thesis Massachusetts Institute of Technology hdl 1721 1 11867 OCLC 32907677 Thomas Peter C Prockter Louise M 28 May 2004 Tectonics of Small Bodies PDF Planetary Tectonics Cambridge Planetary Science Vol 11 Cambridge University Press ISBN 978 0 521 76573 2 Archived from the original PDF on 4 March 2009 Retrieved 29 November 2008 Other edit Belton Michael J S Carlson R 12 March 1994 1993 243 1 IAU Circular 5948 5948 2 Bibcode 1994IAUC 5948 2B Byrnes Dennis V D Amario Louis A Galileo Navigation Team December 1994 Solving for Dactyl s Orbit and Ida s Density The Galileo Messenger 35 Archived from the original on 5 January 1997 Retrieved 23 October 2008 Chapman Clark R Belton Michael J S Veverka Joseph Neukum G Head J Greeley Ronald Klaasen K Morrison D March 1994 First Galileo image of asteroid 243 Ida Abstracts of the 25th Lunar and Planetary Science Conference 237 238 Bibcode 1994LPI 25 237C Cowen Ron 2 October 1993 Close up of an asteroid Galileo eyes Ida Science News Vol 144 no 14 p 215 ISSN 0036 8423 Cowen Ron 1 April 1995 Idiosyncrasies of Ida asteroid 243 Ida s irregular gravitational field PDF Science News Vol 147 no 15 p 207 ISSN 0036 8423 Archived from the original PDF on 27 March 2012 Retrieved 26 March 2009 Greeley Ronald Sullivan Robert J Pappalardo R Head J Veverka Joseph Thomas Peter C Lee P Belton M Chapman Clark R March 1994 Morphology and Geology of Asteroid Ida Preliminary Galileo Imaging Observations Abstracts of the 25th Lunar and Planetary Science Conference 469 470 Bibcode 1994LPI 25 469G Green Daniel W E 26 September 1994 1993 243 1 243 Ida I Dactyl IAU Circular 6082 6082 2 Bibcode 1994IAUC 6082 2G Holm Jeanne June 1994 Jones Jan ed Discovery of Ida s Moon Indicates Possible Families of Asteroids The Galileo Messenger 34 Archived from the original on 24 June 2010 Retrieved 23 October 2008 Alt URL Raab Herbert 2002 Johann Palisa the most successful visual discoverer of asteroids PDF Meeting on Asteroids and Comets in Europe Archived from the original PDF on 30 October 2008 Retrieved 23 October 2008 Sarneczky K Kereszturi A March 2002 Global Tectonism on Asteroids PDF 33rd Annual Lunar and Planetary Science Conference 1381 Bibcode 2002LPI 33 1381S Archived PDF from the original on 26 January 2005 Retrieved 22 October 2008 Stooke P J 1997 Reflections on the Geology of 243 Ida PDF Lunar and Planetary Science XXVIII 1385 1386 Bibcode 1997LPI 28 1385S Archived PDF from the original on 4 March 2009 Retrieved 29 November 2008 JPL Small Body Database Browser 243 Ida Jet Propulsion Laboratory 25 August 2008 Images of Asteroids Ida amp Dactyl National Aeronautics and Space Administration 23 August 2005 Archived from the original on 21 October 2008 Retrieved 4 December 2008 Gazetteer of Planetary Nomenclature Ida United States Geological Survey Astrogeology Research Program Retrieved 15 April 2009 External links edit nbsp Wikimedia Commons has media related to 243 Ida Asteroids with Satellites Robert Johnston johnstonsarchive net 243 Ida at AstDyS 2 Asteroids Dynamic Site Ephemeris Observation prediction Orbital info Proper elements Observational info 243 Ida at the JPL Small Body Database nbsp Close approach Discovery Ephemeris Orbit diagram Orbital elements Physical parameters Portals nbsp Astronomy nbsp Stars nbsp Spaceflight nbsp Outer space nbsp Solar System Retrieved from https en wikipedia org w index php title 243 Ida amp oldid 1213575863 Dactyl, 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