Ganymede (moon)

Ganymede
True-color image taken by the Galileo probe
Image of Ganymede's anti-Jovian hemisphere taken by the Galileo probe. Lighter surfaces, such as in recent impacts, grooved terrain and the whitish north polar cap at upper right, are enriched in water ice.
Discovery
Discovered by G. Galilei
S. Marius
Discovery date January 7, 1610[1][2][3]
Designations
Alternate name(s) Jupiter III
Adjective Ganymedian, Ganymedean
Periapsis 1,069,200 km[b]
Apoapsis 1,071,600 km[a]
Semi-major axis 1,070,400 km[4]
Eccentricity 0.0013[4]
Orbital period 7.15455296 d[4]
Average orbital speed 10.880 km/s
Inclination 0.20° (to Jupiter's equator)[4]
Satellite of Jupiter
Physical characteristics
Mean radius 2634.1 ± 0.3 km (0.413 Earths)[5]
Surface area 87.0 million km2 (0.171 Earths)[c]
Volume 7.6 × 1010 km3 (0.0704 Earths)[d]
Mass 1.4819 × 1023 kg (0.025 Earths)[5]
Mean density 1.936 g/cm3[5]
Equatorial surface gravity 1.428 m/s2 (0.146 g)[e]
Escape velocity 2.741 km/s[f]
Rotation period synchronous
Axial tilt 0–0.33°[6]
Albedo 0.43 ± 0.02[7]
Surface temp.
   K
min mean max
70[9] 110[9] 152[10]
Apparent magnitude 4.61 (opposition)[7]
4.38 (in 1951)[8]
Atmosphere
Surface pressure trace
Composition oxygen[11]

Ganymede (pronounced /ˈɡænɨmiːd/,[12] from the figure of Ganymede in Greek mythology) is a satellite of Jupiter and the largest satellite in the Solar System. It is the seventh moon and third Galilean satellite outward from Jupiter.[13] Completing an orbit in roughly seven days, Ganymede participates in a 1:2:4 orbital resonance with the moons Europa and Io, respectively. It has a diameter of 5,268 km (3270 miles), 8% larger than that of the planet Mercury, but has only 45% of the latter's mass.[14] Its diameter is 2% larger than that of Titan, the second largest moon. It also has the highest mass of all planetary satellites, with 2.02 times the mass of the Earth's moon.[15]

Ganymede is composed of approximately equal amounts of silicate rock and water ice. It is a fully differentiated body with an iron-rich, liquid core. A saltwater ocean is believed to exist nearly 200 km below Ganymede's surface, sandwiched between layers of ice.[16] Its surface is composed of two main types of terrain. Dark regions, saturated with impact craters and dated to four billion years ago, cover about a third of the satellite. Lighter regions, crosscut by extensive grooves and ridges and only slightly less ancient, cover the remainder. The cause of the light terrain's disrupted geology is not fully known, but was likely the result of tectonic activity brought about by tidal heating.[5]

Ganymede is the only satellite in the Solar System known to possess a magnetosphere, likely created through convection within the liquid iron core.[17] The meager magnetosphere is buried within Jupiter's much larger magnetic field and connected to it through open field lines. The satellite has a thin oxygen atmosphere that includes O, O2, and possibly O3 (ozone).[11] Atomic hydrogen is a minor atmospheric constituent. Whether the satellite has an ionosphere associated with its atmosphere is unresolved.[18]

Ganymede's discovery is credited to Galileo Galilei, who was the first to observe it on January 7, 1610.[1][2][3] The satellite's name was soon suggested by astronomer Simon Marius, for the mythological Ganymede, cupbearer of the Greek gods and Zeus's beloved.[19] Beginning with Pioneer 10, spacecraft have been able to examine Ganymede closely.[20] The Voyager probes refined measurements of its size, while the Galileo craft discovered its underground ocean and magnetic field. A new mission to Jupiter's icy moons, the Europa Jupiter System Mission (EJSM) is proposed for a launch in 2020.

The radiation level at the surface of Ganymede is equivalent to a dose of about 8 rem (80 mSv) per day.[21]

Contents

Discovery and naming

On January 7, 1610, Galileo Galilei observed what he believed were three stars near Jupiter, including what turned out to be Ganymede, Callisto, and one star that turned out to be the combined light from Io and Europa; the next night he noticed that they had moved. On January 13, he saw all four at once for the first time, but had seen each of the moons before this date at least once. By January 15, Galileo came to the conclusion that the stars were actually bodies orbiting Jupiter.[1][2][3] He claimed the right to name the moons; he considered "Cosmian Stars" and settled on "Medicean Stars".[19]

Size comparison of Earth and Ganymede.

The French astronomer Nicolas-Claude Fabri de Peiresc suggested individual names from the Medici family for the moons, but his proposal was not taken up.[19] Simon Marius, who had originally claimed to have found the Galilean satellites,[22] tried to name the moons the "Saturn of Jupiter", the "Jupiter of Jupiter" (this was Ganymede), the "Venus of Jupiter", and the "Mercury of Jupiter", another nomenclature that never caught on. From a suggestion by Johannes Kepler, Marius once again tried to name the moons:[19]

... Then there was Ganymede, the handsome son of King Tros, whom Jupiter, having taken the form of an eagle, transported to heaven on his back, as poets fabulously tell ... the Third, on account of its majesty of light, Ganymede ...[23]

This name and those of the other Galilean satellites fell into disfavor for a considerable time, and were not in common use until the mid-20th century. In much of the earlier astronomical literature, Ganymede is referred to instead by its Roman numeral designation (a system introduced by Galileo) as Jupiter III or as the "third satellite of Jupiter". Following the discovery of moons of Saturn, a naming system based on that of Kepler and Marius was used for Jupiter's moons.[19] Ganymede is the only Galilean moon of Jupiter named after a male figure — like Io, Europa, and Callisto, he was a lover of Zeus.

Orbit and rotation

Ganymede orbits Jupiter at a distance of 1,070,400 km, third among the Galilean satellites,[13] and completes a revolution every seven days and three hours. Like most known moons, Ganymede is tidally locked, with one side of the moon always facing toward the planet.[24] Its orbit is very slightly eccentric and inclined to the Jovian equator, with the eccentricity and inclination changing quasi-periodically due to solar and planetary gravitational perturbations on a timescale of centuries. The ranges of change are 0.0009–0.0022 and 0.05–0.32°, respectively.[25] These orbital variations cause the axial tilt (the angle between rotational and orbital axes) to vary between 0 and 0.33°.[6]

The Laplace resonances of Ganymede, Europa, and Io

Ganymede participates in orbital resonances with Europa and Io: for every orbit of Ganymede, Europa orbits twice and Io orbits four times.[25][26] The superior conjunction between Io and Europa always occurs when Io is at periapsis and Europa at apoapsis. The superior conjunction between Europa and Ganymede occurs when Europa is at periapsis.[25] The longitudes of the Io–Europa and Europa–Ganymede conjunctions change with the same rate, making the triple conjunctions impossible. Such a complicated resonance is called the Laplace resonance.[27]

The current Laplace resonance is unable to pump the orbital eccentricity of Ganymede to a higher value.[27] The value of about 0.0013 is probably a remnant from a previous epoch, when such pumping was possible.[26] The ganymedian orbital eccentricity is somewhat puzzling; if it is not pumped now it should have decayed long ago due to the tidal dissipation in the interior of Ganymede.[27] This means that the last episode of the eccentricity excitation happened only several hundred million years ago.[27] Because the orbital eccentricity of Ganymede is relatively low—0.0015 on average[26]—the tidal heating of this moon is negligible now.[27] However, in the past Ganymede may have passed through one or more Laplace-like resonances[j] which were able to pump the orbital eccentricity to a value as high as 0.01–0.02.[5][27] This probably caused a significant tidal heating of the interior of Ganymede; the formation of the grooved terrain may be a result of one or more heating episodes.[5][27]

There are two hypotheses for the origin of the Laplace resonance among Io, Europa, and Ganymede: that it is primordial and has existed from the beginning of the Solar System;[28] or that it developed after the formation of the Solar System. A possible sequence of events for the latter scenario is as follows: Io raised tides on Jupiter, causing its orbit to expand until it encountered the 2:1 resonance with Europa; after that the expansion continued, but some of the angular moment was transferred to Europa as the resonance caused its orbit to expand as well; the process continued until Europa encountered the 2:1 resonance with Ganymede.[27] Eventually the drift rates of conjunctions between all three moons were synchronized and locked in the Laplace resonance.[27]

Physical characteristics

Composition

A sharp boundary divides the ancient dark terrain of Nicholson Regio from the younger, finely striated bright terrain of Harpagia Sulcus.

The average density of Ganymede, 1.936 g/cm3, suggests a composition of approximately equal parts rocky material and water, which is mainly in the form of ice.[5] The mass fraction of ices is between 46–50%, slightly lower than that in Callisto.[29] Some additional volatile ices such as ammonia may also be present.[29][30] The exact composition of Ganymede's rock is not known, but is probably close to the composition of L/LL type ordinary chondrites, which are characterized by less total iron, less metallic iron and more iron oxide than H chondrites. The weight ratio of iron to silicon is 1.05–1.27 in Ganymede, whereas the solar ratio is around 1.8.[29]

Ganymede's surface has an albedo of about 43%.[31] Water ice seems to be ubiquitous on the surface, with a mass fraction of 50–90%,[5] significantly more than in Ganymede as a whole. Near-infrared spectroscopy has revealed the presence of strong water ice absorption bands at wavelengths of 1.04, 1.25, 1.5, 2.0 and 3.0 μm.[31] The grooved terrain is brighter and has more icy composition than the dark terrain.[32] The analysis of high-resolution, near-infrared and UV spectra obtained by the Galileo spacecraft and from the ground has revealed various non-water materials: carbon dioxide, sulfur dioxide and, possibly, cyanogen, hydrogen sulfate and various organic compounds.[5][33] Galileo results have also shown magnesium sulfate (MgSO4) and, possibly, sodium sulfate (Na2SO4) on Ganymede's surface.[24][34] These salts may originate from the subsurface ocean.[34]

The ganymedian surface is asymmetric; the leading hemisphere—that facing the direction of the orbital motion[g]—is brighter than the trailing one.[31] This is similar to Europa, but the reverse is true for Callisto.[31] The trailing hemisphere of Ganymede appears to be enriched in sulfur dioxide.[35][36] The distribution of carbon dioxide does not demonstrate any hemispheric asymmetry, although it is not observed near the poles.[33][37] Impact craters on Ganymede (except one) do not show any enrichment in carbon dioxide, which also distinguishes it from Callisto. Ganymede's carbon dioxide levels were probably depleted in the past.[37]

Internal structure

Model of Ganymede's interior showing a cold rigid ice crust, an outer warm ice mantle, an inner silicate mantle, and a metallic core.

Ganymede appears to be fully differentiated, consisting of an iron sulfide–iron core, silicate mantle and an outer ice mantle.[5][38] This model is supported by the low value of its dimensionless[h] moment of inertia (0.3105 ± 0.0028) which was measured during Galileo flybys.[5][38] In fact, Ganymede has the lowest moment of inertia among the solid solar system bodies. The existence of a liquid, iron-rich core provides a natural explanation for the intrinsic magnetic field of Ganymede detected by Galileo.[39] The convection in the liquid iron, which has high electrical conductivity, is the most reasonable model of magnetic field generation.[17]

The precise thicknesses of the different layers in the interior of Ganymede depend on the assumed composition of silicates (fraction of olivine and pyroxene) and amount of sulfur in the core.[29][38] The most probable values are 700–900 km for the core radius and 800–1000 km for the thickness of the outer ice mantle, with the remainder being made by the silicate mantle.[38][39][40][41] The density of the core is 5.5–6 g/cm3 and the silicate mantle is 3.4–3.6 g/cm3.[29][38][39][40] Some models of the magnetic field generation require the existence of a solid core made of pure iron inside the liquid Fe–FeS core—similar to the structure of the Earth's core. The radius of this core may be up to 500 km.[39] The temperature in the core of Ganymede is probably 1500–1700 K and pressure up to 10 GPa.[38][39]

Surface features

Voyager 2 image mosaic of Ganymede's anti-Jovian hemisphere. The ancient dark area of Galileo Regio lies at the upper right. It is separated from the smaller dark region of Marius Regio to its left by the brighter and younger band of Uruk Sulcus. Fresh ice ejected from the relatively recent Osiris Crater created the bright rays at the bottom.
Depiction of Ganymede centered over 45° W. longitude. The upper and lower dark areas are Perrine and Nicholson regions; the bright-rayed craters are Tros (upper right) and Cisti (lower left).

The Ganymedian surface is a mix of two types of terrain: very old, highly cratered, dark regions and somewhat younger (but still ancient), lighter regions marked with an extensive array of grooves and ridges. The dark terrain, which comprises about one-third of the surface,[42] contains clays and organic materials that could indicate the composition of the impactors from which Jovian satellites accreted.[43]

The heating mechanism required for the formation of the grooved terrain on Ganymede is an unsolved problem in the planetary sciences. The modern view is that the grooved terrain is mainly tectonic in nature.[5] Cryovulcanism is thought to have played only a minor role, if any.[5] The forces that caused the strong stresses in the ganymedian ice lithosphere necessary to initiate the tectonic activity may be connected to the tidal heating events in the past, possibly caused when the satellite passed through unstable orbital resonances.[5][44] The tidal flexing of the ice may have heated the interior and strained the lithosphere, leading to the development of cracks and horst and graben faulting, which erased the old, dark terrain on 70% of the surface.[5][45] The formation of the grooved terrain may also be connected with the early core formation and subsequent tidal heating of the moon's interior, which may have caused a slight expansion of Ganymede by 1–6% due to phase transitions in ice and thermal expansion.[5] During subsequent evolution deep, hot water plumes may have risen from the core to the surface, leading to the tectonic deformation of the lithosphere.[46] Radiogenic heating within the satellite is the most relevant current heat source, contributing, for instance, to thickness of the ocean. Research models have found that if the orbital eccentricity were an order of magnitude greater than current (as it may have been in the past), tidal heating would be a more substantial heat source than radiogenic heating.[47]

The craters Gula and Achelous (bottom), in the grooved terrain of Ganymede, with ejecta "pedestals" and ramparts

Cratering is seen on both types of terrain, but is especially extensive on the dark terrain: it appears to be saturated with impact craters and has evolved largely through impact events.[5] The brighter, grooved terrain contains many fewer impact features, which have been only of a minor importance to its tectonic evolution.[5] The density of cratering indicates an age of 4 billion years for the dark terrain, similar to the highlands of the Moon, and a somewhat younger age for the grooved terrain (but how much younger is uncertain).[48] Ganymede may have experienced a period of heavy cratering 3.5 to 4 billion years ago similar to that of the Moon.[48] If true, the vast majority of impacts happened in that epoch, while the cratering rate has been much smaller since.[15] Craters both overlay and are crosscut by the groove systems, indicating that some of the grooves are quite ancient. Relatively young craters with rays of ejecta are also visible.[15][49] Ganymedian craters are flatter than those on the Moon and Mercury. This is probably due to the relatively weak nature of Ganymede's icy crust, which can (or could) flow and thereby soften the relief. Ancient craters whose relief has disappeared leave only a "ghost" of a crater known as a palimpsest.[15]

One significant feature on Ganymede is a dark plain named Galileo Regio, which contains a series of concentric grooves, or furrows, likely created during a period of geologic activity.[50]

Ganymede also has polar caps, likely composed of water frost. The frost extends to 40° latitude.[24] These polar caps were first seen by the Voyager spacecraft. Theories on the caps' formation include the migration of water to higher latitudes and bombardment of the ice by plasma. Data from Galileo suggests the latter is correct.[51] The presence of a magnetic field on Ganymede results in more intense charged particle bombardment of its surface in the unprotected polar regions; sputtering then leads to redistribution of water molecules, with frost migrating to locally colder areas within the polar terrain.[51]

Atmosphere and ionosphere

In 1972, a team of Indian, British and American astronomers working at Indonesia's Bosscha Observatory claimed that they had detected a thin atmosphere around the satellite during an occultation, when it and Jupiter passed in front of a star.[52] They estimated that the surface pressure was around 0.1 Pa.[52] However, in 1979 Voyager 1 observed an occultation of a star (κ Centauri) during its flyby of the planet, with differing results.[53] The occultation measurements were conducted in the far-ultraviolet spectrum at wavelengths shorter than 200 nm; they were much more sensitive to the presence of gases than the 1972 measurements in the visible spectrum. No atmosphere was revealed by the Voyager data. The upper limit on the surface particle number density was found to be 1.5 × 109 cm−3, which corresponds to a surface pressure of less than 2.5 µPa.[53] The latter value is almost five orders of magnitude less than the 1972 estimate.[53]

Despite the Voyager data, evidence for a tenuous oxygen atmosphere on Ganymede, very similar to the one found on Europa, was found by the Hubble Space Telescope (HST) in 1995.[11][54] HST actually observed airglow of atomic oxygen in the far-ultraviolet at the wavelengths 130.4 nm and 135.6 nm. Such an airglow is excited when molecular oxygen is dissociated by electron impacts,[11] evidence of a significant neutral atmosphere composed predominantly of O2 molecules. The surface number density probably lies in the 1.2 × 108–7 × 108 cm−3 range, corresponding to the surface pressure of 0.2–1.2 µPa.[11][i] These values are in agreement with the Voyager's upper limit set in 1981. The oxygen is not evidence of life; it is thought to be produced when water ice on Ganymede's surface is split into hydrogen and oxygen by radiation, with the hydrogen then being more rapidly lost due to its low atomic mass.[54] The airglow observed over Ganymede is not spatially homogeneous like that over Europa. HST observed two bright spots located in the northern and southern hemispheres, near ± 50° latitude, which is exactly the boundary between the open and closed field lines of the ganymedian magnetosphere (see below).[55] The bright spots are probably polar auroras, caused by plasma precipitation along the open field lines.[56]

False color temperature map of Ganymede

The existence of a neutral atmosphere implies that an ionosphere should exist, because oxygen molecules are ionized by the impacts of the energetic electrons coming from the magnetosphere[57] and by solar EUV radiation.[18] However, the nature of the ganymedian ionosphere is as controversial as the nature of the atmosphere. Some Galileo measurements found an elevated electron density near the moon, suggesting an ionosphere, while others failed to detect anything.[18] The electron density near the surface is estimated by different sources to lie in the range 400–2,500 cm−3.[18] As of 2008, the parameters of the ionosphere of Ganymede are not well constrained.

Additional evidence of the oxygen atmosphere comes from spectral detection of gases trapped in the ice at the surface of Ganymede. The detection of ozone (O3) bands was announced in 1996.[58] In 1997 spectroscopic analysis revealed the dimer (or diatomic) absorption features of molecular oxygen. Such an absorption can arise only if the oxygen is in a dense phase. The best candidate is molecular oxygen trapped in ice. The depth of the dimer absorption bands depends on latitude and longitude, rather than on surface albedo—they tend to decrease with increasing latitude on Ganymede, while O3 shows an opposite trend.[59] Laboratory work has found that O2 would not cluster or bubble but dissolve in ice at Ganymede's relatively warm surface temperature of 100 K.[60]

A search for sodium in the atmosphere, just after such a finding on Europa, turned up nothing in 1997. Sodium is at least 13 times less abundant around Ganymede than around Europa, possibly because of a relative deficiency at the surface or because the magnetosphere fends off energetic particles.[61] Another minor constituent of the Ganymedian atmosphere is atomic hydrogen. Hydrogen atoms were observed as far as 3,000 km from the surface of the moon. Their density on the surface is about 1.5 × 104 cm−3.[62]

Magnetosphere

Enhanced-color Galileo spacecraft image of Ganymede's trailing hemisphere.[63] The crater Tashmetum's prominent rays are at lower right, and the large ejecta field of Hershef at upper right. Part of dark Nicholson Regio is at lower left, bounded on its upper right by Harpagia Sulcus.

The Galileo craft made six close flybys of Ganymede from 1995–2000 (G1, G2, G7, G8, G28 and G29)[17] and discovered that Ganymede has a permanent (intrinsic) magnetic moment independent of the Jovian magnetic field.[64] The value of the moment is about 1.3 × 1013 T·m3,[17] which is three times larger than the magnetic moment of Mercury. The magnetic dipole is tilted with respect to the rotational axis of Ganymede by 176°, which means that it is directed against the Jovian magnetic moment.[17] Its north pole lies below the orbital plane. The dipole magnetic field created by this permanent moment has a strength of 719 ± 2 nT at the equator of the moon,[17] which should be compared with the Jovian magnetic field at the distance of Ganymede—about 120 nT.[64] The equatorial field of Ganymede is directed against the Jovian field, meaning reconnection is possible. The intrinsic field strength at the poles is two times that at the equator—1440 nT.[17]

The permanent magnetic moment carves a part of space around Ganymede, creating a tiny magnetosphere embedded inside that of Jupiter; it is the only moon in the Solar System known to possess the feature.[64] Its diameter is 4–5 RG (RG = 2,631.2 km).[65] The ganymedian magnetosphere has a region of closed field lines located below 30° latitude, where charged particles (electrons and ions) are trapped, creating a kind of radiation belt.[65] The main ion species in the magnetosphere is single ionized oxygen—O+[18]—which fits well with the tenuous oxygen atmosphere of the moon. In the polar cap regions, at latitudes higher than 30°, magnetic field lines are open, connecting Ganymede with Jupiter's ionosphere.[65] In these areas, the energetic (tens and hundreds of kiloelectronvolt) electrons and ions have been detected,[57] which may be responsible for the auroras observed around the ganymedian poles.[55] In addition, heavy ions continuously precipitate on the polar surface of the moon, sputtering and darkening the ice.[57]

Magnetic field of the Jovian satellite Ganymede, which is embedded into the magnetosphere of Jupiter. Closed field lines are marked with green color.

The interaction between the ganymedian magnetosphere and Jovian plasma is in many respects similar to that of the solar wind and Earth's magnetosphere.[65][66] The plasma co-rotating with Jupiter impinges on the trailing side of the ganymedian magnetosphere much like the solar wind impinges on the Earth's magnetosphere. The main difference is the speed of plasma flow—supersonic in the case of Earth and subsonic in the case of Ganymede. Because of the subsonic flow, there is no bow shock off the trailing hemisphere of Ganymede.[66]

In addition to the intrinsic magnetic moment, Ganymede has an induced dipole magnetic field.[17] Its existence is connected with the variation of the Jovian magnetic field near the moon. The induced moment is directed radially to or from Jupiter following the direction of the varying part of the planetary magnetic field. The induced magnetic moment is an order of magnitude weaker than the intrinsic one. The field strength of the induced field at the magnetic equator is about 60 nT—half of that of the ambient Jovian field.[17] The induced magnetic field of Ganymede is similar to those of Callisto and Europa, indicating that this moon also has a subsurface water ocean with a high electrical conductivity.[17]

Given that Ganymede is completely differentiated and has a metallic core,[5][39] its intrinsic magnetic field is probably generated in a similar fashion to the Earth's: as a result of conducting material moving in the interior.[17][39] The magnetic field detected around Ganymede is likely to be caused by compositional convection in the core,[39] if the magnetic field is the product of dynamo action, or magnetoconvection.[17][67]

Despite the presence of an iron core, Ganymede's magnetosphere remains enigmatic, particularly given that similar bodies lack the feature.[5] Some research has suggested that, given its relatively small size, the core ought to have sufficiently cooled to the point where fluid motions and a magnetic field would not be sustained. One explanation is that the same orbital resonances proposed to have disrupted the surface also allowed the magnetic field to persist: with Ganymede's eccentricity pumped and tidal heating increased during such resonances, the mantle may have insulated the core, preventing it from cooling.[45] Another explanation is a remnant magnetization of silicate rocks in the mantle, which is possible if the satellite had a more significant dynamo-generated field in the past.[5]

Origin and evolution

Ganymede likely formed by an accretion in Jupiter's subnebula, a disk of gas and dust surrounding Jupiter after its formation.[68] The accretion of Ganymede probably took about 10,000 years,[69] much shorter than the 100,000 years estimated for Callisto. The Jovian subnebula may have been relatively "gas-starved" when the Galilean satellites formed; this would have allowed for the lengthy accretion times required for Callisto.[68] In contrast Ganymede formed closer to Jupiter, where the subnebula was denser, which explains its shorter formation timescale.[69] This relatively fast formation prevented the escape of accretional heat, which may have led to ice melt and differentiation: the separation of the rocks and ice. The rocks settled to the center, forming the core. In this respect, Ganymede is different from Callisto, which apparently failed to melt and differentiate early due to loss of the accretional heat during its slower formation.[70] This hypothesis explains why the two Jovian moons look so dissimilar, despite their similar mass and composition.[41][70] Alternative theories explain Ganymede's greater internal heating on the basis of tidal flexing[71] or more intense pummeling by impactors during the Late Heavy Bombardment.[72][73][74]

After formation, the Ganymedian core largely retained the heat accumulated during accretion and differentiation, only slowly releasing it to the ice mantle like a kind of thermal battery.[70] The mantle, in turn, transported it to the surface by convection.[41] Soon the decay of radioactive elements within rocks further heated the core, causing increased differentiation: an inner, iron–iron sulfide core and a silicate mantle formed.[39][70] With this, Ganymede became a fully differentiated body. By comparison, the radioactive heating of undifferentiated Callisto caused convection in its icy interior, which effectively cooled it and prevented large-scale melting of ice and rapid differentiation.[75] The convective motions in Callisto have caused only a partial separation of rock and ice.[75] Today, Ganymede continues to cool slowly.[39] The heat being released from its core and silicate mantle enables the subsurface ocean to exist,[30] while the slow cooling of the liquid Fe–FeS core causes convection and supports magnetic field generation.[39] The current heat flux out of Ganymede is probably higher than that out of Callisto.[70]

Coordinate system

A crater named Anat provides the reference point for measuring longitude on Ganymede. By definition, Anat is at 128 degrees longitude.[76]

Exploration

Several probes flying by or orbiting Jupiter have explored Ganymede in detail. The first probes to explore were Pioneer 10 and Pioneer 11,[20] neither of which returned much information about the satellite.[77] Voyager 1 and Voyager 2 were next, passing by Ganymede in 1979. They refined its size, revealing it was larger than Saturn's moon Titan, which was previously thought to have been bigger.[78] The grooved terrain was also seen.[79]

In 1995, the Galileo spacecraft entered orbit around Jupiter and between 1996 and 2000 made six close flybys to explore Ganymede.[24] These flybys are G1, G2, G7, G8, G28 and G29.[17] During the closest flyby—G2—Galileo passed just 264 km from the surface of Ganymede.[17] During a G1 flyby in 1996, the ganymedian magnetic field was discovered,[80] while the discovery of the ocean was announced in 2001.[17][24] Galileo transmitted a large number of spectral images and discovered several non-ice compounds on the surface of Ganymede.[33] The most recent spacecraft to explore Ganymede up close was New Horizons, which passed by in 2007 on its way to Pluto. New Horizons made topography and composition maps of Ganymede as it sped by.[81][82]

Proposed for a launch in 2020, the Europa Jupiter System Mission (EJSM) is a joint NASA and ESA proposal for exploration of Jupiter's moons. In February 2009 it was announced that ESA and NASA had given this mission priority ahead of the Titan Saturn System Mission.[83] ESA's contribution will still face funding competition from other ESA projects.[84] EJSM consists of the NASA-led Jupiter Europa Orbiter, the ESA-led Jupiter Ganymede Orbiter, and possibly a JAXA-led Jupiter Magnetospheric Orbiter.

One canceled proposal to orbit Ganymede was the Jupiter Icy Moons Orbiter. Nuclear fission would have been used to power the craft, which would have been able to study Ganymede in detail.[85] However, the mission was canceled in 2005 because of budget cuts.[86] Another old proposal was called The Grandeur of Ganymede.[43]

See also

Notes

  1. ^ Apoapsis is derived from the semimajor axis (a) and eccentricity (e): a*(1+e).
  2. ^ Periapsis is derived from the semimajor axis (a) and eccentricity (e): a*(1-e).
  3. ^ Surface area derived from the radius (r): 4\pi r^2.
  4. ^ Volume derived from the radius (r): 4\pi r^3/3.
  5. ^ Surface gravity derived from the mass (m), the gravitational constant (G) and the radius (r): Gm/r^2.
  6. ^ Escape velocity derived from the mass (m), the gravitational constant (G) and the radius (r): \textstyle\sqrt{\frac{2Gm}{r}}.
  7. ^ The leading hemisphere is the hemisphere facing the direction of orbital motion; the trailing hemisphere faces the reverse direction.
  8. ^ The dimensionless moment of inertia referred to is I / (mr2), where I is the moment of inertia, m the mass, and r the maximal radius. It is 0.4 for a homogenous spherical body, but less than 0.4 if density increases with depth.
  9. ^ The surface number density and pressure were calculated from the column densities reported in Hall, et al. 1998, assuming a scale height of 20 km and temperature 120 K.
  10. ^ A Laplace-like resonance is similar to the current Laplace resonance among the Galilean moons with the only difference being that longitudes of the Io–Europa and Europa–Ganymede conjunctions change with rates, whose ratio is a rational number—not unity as in the case of the Laplace resonance.

References

  1. 1.0 1.1 1.2 Galilei, Galileo; translated by Edward Carlos and edited by Peter Barker (March 1610). "Sidereus Nuncius" (PDF). University of Oklahoma History of Science. http://hsci.cas.ou.edu/images/barker/5990/Sidereus-Nuncius-whole.pdf. Retrieved 2010-01-13. 
  2. 2.0 2.1 2.2 Wright, Ernie. "Galileo's First Observations of Jupiter" (PDF). University of Oklahoma History of Science. http://home.comcast.net/~erniew/astro/sidnunj1.html. Retrieved 2010-01-13. 
  3. 3.0 3.1 3.2 "NASA: Ganymede". Solarsystem.nasa.gov. 2009-09-29. http://solarsystem.nasa.gov/planets/profile.cfm?Object=Jup_Ganymede. Retrieved 2010-03-08. 
  4. 4.0 4.1 4.2 4.3 "Planetary Satellite Mean Orbital Parameters". Jet Propulsion Laboratory, California Institute of Technology. http://ssd.jpl.nasa.gov/?sat_elem. 
  5. 5.00 5.01 5.02 5.03 5.04 5.05 5.06 5.07 5.08 5.09 5.10 5.11 5.12 5.13 5.14 5.15 5.16 5.17 5.18 5.19 5.20 Showman, Adam P.; Malhotra, Renu (1999). "The Galilean Satellites" (PDF). Science 286 (5437): 77–84. doi:10.1126/science.286.5437.77. PMID 10506564. http://www.lpl.arizona.edu/~showman/publications/showman-malhotra-1999.pdf. 
  6. 6.0 6.1 Bills, Bruce G. (2005). "Free and forced obliquities of the Galilean satellites of Jupiter". Icarus 175: 233–247. doi:10.1016/j.icarus.2004.10.028. http://adsabs.harvard.edu/abs/2005Icar..175..233B. 
  7. 7.0 7.1 Yeomans, Donald K. (2006-07-13). "Planetary Satellite Physical Parameters". JPL Solar System Dynamics. http://ssd.jpl.nasa.gov/?sat_phys_par. Retrieved 2007-11-05. 
  8. Yeomans and Chamberlin. "Horizon Online Ephemeris System for Ganymede (Major Body 503)". California Institute of Technology, Jet Propulsion Laboratory. http://ssd.jpl.nasa.gov/horizons.cgi?find_body=1&body_group=mb&sstr=503. Retrieved 2010-04-14.  (4.38 on 1951-Oct-03)
  9. 9.0 9.1 Delitsky, Mona L.; Lane, Arthur L. (1998). "Ice chemistry of Galilean satellites" (PDF). J.of Geophys. Res. 103 (E13): 31,391–31,403. doi:10.1029/1998JE900020. http://trs-new.jpl.nasa.gov/dspace/bitstream/2014/20675/1/98-1725.pdf. 
  10. Orton, G.S.; Spencer, G.R.; Travis, L.D. et al. (1996). "Galileo Photopolarimeter-radiometer observations of Jupiter and the Galilean Satellites". Science 274: 389–391. doi:10.1126/science.274.5286.389. http://adsabs.harvard.edu/abs/1996Sci...274..389O. 
  11. 11.0 11.1 11.2 11.3 11.4 Hall, D.T.; Feldman, P.D.; McGrath, M.A. et al. (1998). "The Far-Ultraviolet Oxygen Airglow of Europa and Ganymede". The Astrophysical Journal 499: 475–481. doi:10.1086/305604. http://adsabs.harvard.edu/abs/1998ApJ...499..475H. 
  12. In US dictionary transcription, us dict: găn′·ı·mēd
  13. 13.0 13.1 "Jupiter's Moons". The Planetary Society. http://www.planetary.org/explore/topics/our_solar_system/jupiter/moons.html. Retrieved 2007-12-07. 
  14. "Ganymede Fact Sheet". www2.jpl.nasa.gov. http://www2.jpl.nasa.gov/galileo/ganymede/. Retrieved 2010-01-14. 
  15. 15.0 15.1 15.2 15.3 "Ganymede". nineplanets.org. October 31, 1997. http://www.nineplanets.org/ganymede.html. Retrieved 2008-02-27. 
  16. "Solar System's largest moon likely has a hidden ocean". Jet Propulsion Laboratory. NASA. 2000-12-16. http://www.jpl.nasa.gov/releases/2000/aguganymederoundup.html. Retrieved 2008-01-11. 
  17. 17.00 17.01 17.02 17.03 17.04 17.05 17.06 17.07 17.08 17.09 17.10 17.11 17.12 17.13 17.14 Kivelson, M.G.; Khurana, K.K.; Coroniti, F.V. et al. (2002). "The Permanent and Inductive Magnetic Moments of Ganymede" (PDF). Icarus 157: 507–522. doi:10.1006/icar.2002.6834. http://www.igpp.ucla.edu/people/mkivelson/Publications/ICRUS1572507.pdf. 
  18. 18.0 18.1 18.2 18.3 18.4 Eviatar, Aharon; Vasyliunas, Vytenis M.; Gurnett, Donald A. et al. (2001). "The ionosphere of Ganymede" (ps). Planet. Space Sci. 49: 327–336. doi:10.1016/S0032-0633(00)00154-9. http://www.tau.ac.il/~arkee/ganymop.ps. 
  19. 19.0 19.1 19.2 19.3 19.4 "Satellites of Jupiter". The Galileo Project. http://galileo.rice.edu/sci/observations/jupiter_satellites.html. Retrieved 2007-11-24. 
  20. 20.0 20.1 "Pioneer 11". Solar System Exploration. http://sse.jpl.nasa.gov/missions/profile.cfm?Sort=Advanced&MCode=Pioneer_11. Retrieved 2008-01-06. 
  21. Frederick A. Ringwald (2000-02-29). "SPS 1020 (Introduction to Space Sciences)". California State University, Fresno. http://zimmer.csufresno.edu/~fringwal/w08a.jup.txt. Retrieved 2009-07-04.  (Webcite from 2009-09-20)
  22. "Discovery". Cascadia Community College. Archived from the original on 2006-09-20. http://web.archive.org/web/20060920121740/http://www.cascadia.ctc.edu/facultyweb/instructors/jvanleer/astro+sum01/astro101/discovery.htm. Retrieved 2007-11-24. 
  23. "The Discovery of the Galilean Satellites". Views of the Solar System. Space Research Institute, Russian Academy of Sciences. Archived from the original on 2007-11-18. http://web.archive.org/web/20071118221327/http://www.iki.rssi.ru/solar/eng/galdisc.htm. Retrieved 2007-11-24. 
  24. 24.0 24.1 24.2 24.3 24.4 Miller, Ron; William K. Hartmann (May 2005). The Grand Tour: A Traveler's Guide to the Solar System (3rd ed.). Thailand: Workman Publishing. pp. 108–114. ISBN 0-7611-3547-2. 
  25. 25.0 25.1 25.2 Musotto, Susanna; Varadi, Ferenc; Moore, William; Schubert, Gerald (2002). "Numerical Simulations of the Orbits of the Galilean Satellites". Icarus 159: 500–504. doi:10.1006/icar.2002.6939. http://adsabs.harvard.edu/abs/2002Icar..159..500M. 
  26. 26.0 26.1 26.2 "High Tide on Europa". SPACE.com. http://www.space.com/searchforlife/seti_tidal_europa_021003.html. Retrieved 2007-12-07. 
  27. 27.0 27.1 27.2 27.3 27.4 27.5 27.6 27.7 27.8 Showman, Adam P.; Malhotra, Renu (1997). "Tidal Evolution into the Laplace Resonance and the Resurfacing of Ganymede" (PDF). Icarus 127: 93–111. doi:10.1006/icar.1996.5669. http://www.lpl.arizona.edu/~showman/publications/showman-malhotra-1997.pdf. 
  28. Peale, S.J.; Lee, Man Hoi (2002). "A Primordial Origin of the Laplace Relation Among the Galilean Satellites". Science 298 (5593): 593–597. doi:10.1126/science.1076557. PMID 12386333. http://adsabs.harvard.edu/abs/2002Sci...298..593P. 
  29. 29.0 29.1 29.2 29.3 29.4 Kuskov, O.L.; Kronrod, V.A. (2005). "Internal structure of Europa and Callisto". Icarus 177: 550–369. doi:10.1016/j.icarus.2005.04.014. http://adsabs.harvard.edu/abs/2005Icar..177..550K. 
  30. 30.0 30.1 Spohn, T.; Schubert, G. (2003). "Oceans in the icy Galilean satellites of Jupiter?" (PDF). Icarus 161: 456–467. doi:10.1016/S0019-1035(02)00048-9. http://lasp.colorado.edu/icymoons/europaclass/Spohn_Schubert_oceans.pdf. 
  31. 31.0 31.1 31.2 31.3 Calvin, Wendy M.; Clark, Roger N.;Brown, Robert H.; and Spencer John R. (1995). "Spectra of the ice Galilean satellites from 0.2 to 5 µm: A compilation, new observations, and a recent summary". J.of Geophys. Res. 100: 19,041–19,048. doi:10.1029/94JE03349. http://adsabs.harvard.edu/abs/1995JGR...10019041C. 
  32. "Ganymede: the Giant Moon". Wayne RESA. Archived from the original on 2007-12-02. http://web.archive.org/web/20071202132022/http://www.resa.net/nasa/ganymede.htm. Retrieved 2007-12-31. 
  33. 33.0 33.1 33.2 McCord, T.B.; Hansen, G.V.; Clark, R.N. et al. (1998). "Non-water-ice constituents in the surface material of the icy Galilelean satellites from Galileo near-infrared mapping spectrometer investigation". J. Of Geophys. Res. 103 (E4): 8,603–8,626. doi:10.1029/98JE00788. http://adsabs.harvard.edu/abs/1998JGR...103.8603M. 
  34. 34.0 34.1 McCord, Thomas B.; Hansen, Gary B.; Hibbitts, Charles A. (2001). "Hydrated Salt Minerals on Ganymede's Surface: Evidence of an Ocean Below". Science 292 (5521): 1523–1525. doi:10.1126/science.1059916. PMID 11375486. http://adsabs.harvard.edu/abs/2001Sci...292.1523M. 
  35. Domingue, Deborah; Lane, Arthur; Moth, Pimol (1996). "Evidence from IUE for Spatial and Temporal Variations in the Surface Composition of the Icy Galilean Satellites". Bulletin of the American Astronomical Society 28: 1070. http://adsabs.harvard.edu/abs/1996DPS....28.0404D. 
  36. Domingue, Deborah L.; Lane, Arthur L.; Beyer, Ross A. (1998). "IEU's detection of tenuous SO2 frost on Ganymede and its rapid time variability". Geophys. Res. Lett. 25 (16): 3,117–3,120. doi:10.1029/98GL02386. http://adsabs.harvard.edu/abs/1998GeoRL..25.3117D. 
  37. 37.0 37.1 Hibbitts, C.A.; Pappalardo, R.; Hansen, G.V.; McCord, T.B. (2003). "Carbon dioxide on Ganymede". J.of Geophys. Res. 108 (E5): 5,036. doi:10.1029/2002JE001956. http://adsabs.harvard.edu/abs/2003JGRE..108.5036H. 
  38. 38.0 38.1 38.2 38.3 38.4 38.5 Sohl, F.; Spohn, T; Breuer, D.; Nagel, K. (2002). "Implications from Galileo Observations on the Interior Structure and Chemistry of the Galilean Satellites". Icarus 157: 104–119. doi:10.1006/icar.2002.6828. http://adsabs.harvard.edu/abs/2002Icar..157..104S. 
  39. 39.00 39.01 39.02 39.03 39.04 39.05 39.06 39.07 39.08 39.09 39.10 Hauk, Steven A.; Aurnou, Jonathan M.; Dombard, Andrew J. (2006). "Sulfur's impact on core evolution and magnetic field generation on Ganymede" (PDF). J. Of Geophys. Res. 111: E09008. doi:10.1029/2005JE002557. http://geology.case.edu/~hauck/papers/hauck_jgr_2006.pdf. 
  40. 40.0 40.1 Kuskov, O.L.; Kronrod, V.A.; Zhidicova, A.P. (2005). "Internal Structure of Icy Satellites of Jupiter" (PDF). Geophysical Research Abstracts (European Geosciences Union) 7: 01892. http://www.cosis.net/abstracts/EGU05/01892/EGU05-J-01892.pdf. 
  41. 41.0 41.1 41.2 Freeman, J. (2006). "Non-Newtonian stagnant lid convection and the thermal evolution of Ganymede and Callisto" (PDF). Planetary and Space Science 54: 2–14. doi:10.1016/j.pss.2005.10.003. Archived from the original on 2007-08-24. http://web.archive.org/web/20070824155106/http://bowfell.geol.ucl.ac.uk/~lidunka/EPSS-papers/pete2.pdf. 
  42. Petterson, Wesley; Head, James W.; Collins, Geoffrey C. et al. (2007). "A Global Geologic Map of Ganymede" (PDF). Lunar and Planetary Science XXXVIII: 1098. http://www.lpi.usra.edu/meetings/lpsc2007/pdf/1098.pdf. 
  43. 43.0 43.1 Pappalardo, R.T.; Khurana, K.K.; Moore, W.B. (2001). "The Grandeur of Ganymede: Suggested Goals for an Orbiter Mission" (PDF). Lunar and Planetary Science XXXII: 4062. http://www.lpi.usra.edu/meetings/outerplanets2001/pdf/4065.pdf. 
  44. Showman, Adam P.; Stevenson, David J.; Malhotra, Renu (1997). "Coupled Orbital and Thermal Evolution of Ganymede" (PDF). Icarus 129: 367–383. doi:10.1006/icar.1997.5778. http://www.lpl.arizona.edu/~showman/publications/showman-etal-1997.pdf. 
  45. 45.0 45.1 Bland; Showman, A.P.; Tobie, G. (March 2007). "Ganymede's orbital and thermal evolution and its effect on magnetic field generation" (PDF). Lunar and Planetary Society Conference 38: 2020. http://www.lpi.usra.edu/meetings/lpsc2007/pdf/2020.pdf. 
  46. Barr, A.C.; Pappalardo, R. T. et al. (2001). "Rise of Deep Melt into Ganymede's Ocean and Implications for Astrobiology" (PDF). Lunar and Planetary Science Conference 32: 1781. http://www.lpi.usra.edu/meetings/lpsc2001/pdf/1781.pdf. 
  47. Huffmann, H.; Sohl, F. et al. (2004). "Internal Structure and Tidal Heating of Ganymede" (PDF). European Geosciences Union, Geophysical Research Abstracts 6. http://www.cosis.net/abstracts/EGU04/05114/EGU04-J-05114.pdf. 
  48. 48.0 48.1 Zahnle, K.; Dones, L. (1998). "Cratering Rates on the Galilean Satellites" (PDF). Icarus 136: 202–222. doi:10.1006/icar.1998.6015. http://lasp.colorado.edu/icymoons/europaclass/Zahnle_etal_1998.pdf. 
  49. "Ganymede". Lunar and Planetary Institute. 1997. http://www.lpi.usra.edu/resources/outerp/gany.html. 
  50. Casacchia, R.; Strom, R.G. (1984). "Geologic evolution of Galileo Regio". Journal of Geophysical Research 89: B419–B428. doi:10.1029/JB089iS02p0B419. Bibcode: 1984LPSC...14..419C. http://adsabs.harvard.edu/abs/1984JGRS...89..419C. 
  51. 51.0 51.1 Khurana, Krishan K.; Pappalardo, Robert T.; Murphy, Nate; Denk, Tilmann (2007). "The origin of Ganymede's polar caps". Icarus 191 (1): 193–202. doi:10.1016/j.icarus.2007.04.022. http://adsabs.harvard.edu/abs/2007Icar..191..193K. 
  52. 52.0 52.1 Carlson, R.W.; Bhattacharyya, J.C.; Smith, B.A. et al. (1973). "Atmosphere of Ganymede from its occultation of SAO 186800 on 7 June 1972". Science 53 (4107): 182. doi:10.1126/science.182.4107.53. PMID 17829812. http://adsabs.harvard.edu/abs/1973Sci...182...53C. 
  53. 53.0 53.1 53.2 Broadfoot, A.L.; Sandel, B.R.; Shemansky, D.E. et al. (1981). "Overview of the Voyager Ultraviolet Spectrometry Results through Jupiter Encounter" (PDF). Science 86: 8259–8284. http://www-personal.umich.edu/~atreya/Articles/1981_Overview_Voyager.pdf. 
  54. 54.0 54.1 "Hubble Finds Thin Oxygen Atmosphere on Ganymede". Jet Propulsion Laboratory. NASA. October 1996. http://www2.jpl.nasa.gov/galileo/hst7.html. Retrieved 2008-01-15. 
  55. 55.0 55.1 Feldman, Paul D.; McGrath, Melissa A.; Strobell, Darrell F. et al. (2000). "HST/STIS Ultraviolet Imaging of Polar Aurora on Ganymede". The Astrophysical Journal 535: 1085–1090. doi:10.1086/308889. http://adsabs.harvard.edu/abs/2000ApJ...535.1085F. 
  56. Johnson, R.E. (1997). "Polar "Caps" on Ganymede and Io Revisited". Icarus 128 (2): 469–471. doi:10.1006/icar.1997.5746. http://adsabs.harvard.edu/abs/1997Icar..128..469J. 
  57. 57.0 57.1 57.2 Paranicas, C.; Paterson, W.R.; Cheng, A.F. et al. (1999). "Energetic particles observations near Ganymede". J.of Geophys. Res. 104 (A8): 17,459–17,469. doi:10.1029/1999JA900199. http://adsabs.harvard.edu/abs/1999JGR...10417459P. 
  58. Noll, Keith S.; Johnson, Robert E. et al. (July 1996). "Detection of Ozone on Ganymede". Science 273 (5273): 341–343. doi:10.1126/science.273.5273.341. PMID 8662517. http://www.sciencemag.org/cgi/content/abstract/273/5273/341. Retrieved 2008-01-13. 
  59. Calvin, Wendy M.; Spencer, John R. (December 1997). "Latitudinal Distribution of O2 on Ganymede: Observations with the Hubble Space Telescope". Icarus 130 (2): 505–516. doi:10.1006/icar.1997.5842. http://adsabs.harvard.edu/abs/1997Icar..130..505C. 
  60. Vidal, R. A.; Bahr, D. et al. (1997). "Oxygen on Ganymede: Laboratory Studies". Science 276 (5320): 1839–1842. doi:10.1126/science.276.5320.1839. PMID 9188525. http://adsabs.harvard.edu/abs/1997Sci...276.1839V. 
  61. Brown, Michael E. (1997). "A Search for a Sodium Atmosphere around Ganymede". Icarus 126 (1): 236–238. doi:10.1006/icar.1996.5675. http://adsabs.harvard.edu/abs/1997Icar..126..236B. 
  62. Barth, C.A.; Hord, C.W.; Stewart, A.I. et al. (1997). "Galileo ultraviolet spectrometer observations of atomic hydrogen in the atmosphere of Ganymede". Geophys. Res. Lett. 24 (17): 2147–2150. doi:10.1029/97GL01927. http://adsabs.harvard.edu/abs/1997GeoRL..24.2147B. 
  63. "Galileo has successful flyby of Ganymede during eclipse". Spaceflight Now. http://spaceflightnow.com/news/n0012/29ganyflyby/. Retrieved 2008-01-19. 
  64. 64.0 64.1 64.2 Kivelson, M.G.; Khurana, K.K.; Coroniti, F.V. et al. (1997). "The magnetic field and magnetosphere of Ganymede" (PDF). Geophys. Res. Lett. 24 (17): 2155–2158. doi:10.1029/97GL02201. http://www.igpp.ucla.edu/people/mkivelson/Publications/97GL02201.pdf. 
  65. 65.0 65.1 65.2 65.3 Kivelson, M.G.; Warnecke, J.; Bennett, L. et al. (1998). "Ganymede's magnetosphere: magnetometer overview" (PDF). J.of Geophys. Res. 103 (E9): 19,963–19,972. doi:10.1029/98JE00227. http://www.igpp.ucla.edu/people/mkivelson/Publications/98JE00227.pdf. 
  66. 66.0 66.1 Volwerk, M.; Kivelson, M.G.; Khurana, K.K.; McPherron, R.L. (1999). "Probing Ganymede's magnetosphere with field line resonances" (PDF). J.of Geophys. Res. 104 (A7): 14,729–14,738. doi:10.1029/1999JA900161. http://www.igpp.ucla.edu/people/mkivelson/Publications/1999JA900161.pdf. 
  67. Hauck, Steven A. (2002). "Internal structure and mechanism of core convection on Ganymede" (PDF). Lunar and Planetary Science XXXIII: 1380. http://www.lpi.usra.edu/meetings/lpsc2002/pdf/1380.pdf. 
  68. 68.0 68.1 Canup, Robin M.; Ward, William R. (2002). "Formation of the Galilean Satellites: Conditions of Accretion" (PDF). The Astronomical Journal 124: 3404–3423. doi:10.1086/344684. http://www.boulder.swri.edu/~robin/cw02final.pdf. 
  69. 69.0 69.1 Mosqueira, Ignacio; Estrada, Paul R (2003). "Formation of the regular satellites of giant planets in an extended gaseous nebula I: subnebula model and accretion of satellites". Icarus 163: 198–231. doi:10.1016/S0019-1035(03)00076-9. http://adsabs.harvard.edu/abs/2003Icar..163..198M. 
  70. 70.0 70.1 70.2 70.3 70.4 McKinnon, William B. (2006). "On convection in ice I shells of outer Solar System bodies, with detailed application to Callisto". Icarus 183: 435–450. doi:10.1016/j.icarus.2006.03.004. http://adsabs.harvard.edu/abs/2006Icar..183..435M. 
  71. Showman, A. P.; Malhotra, R. (1997-03). "Tidal evolution into the Laplace resonance and the resurfacing of Ganymede". Icarus (Elsevier) 127 (1): 93–111. doi:10.1006/icar.1996.5669. 
  72. Baldwin, E. (2010-01-25). "Comet impacts explain Ganymede-Callisto dichotomy". Astronomy Now Online. Astronomy Now. http://www.astronomynow.com/news/n1001/25galilean/. Retrieved 2010-03-01. 
  73. Barr, A. C.; Canup, R. M. (March 2010). "Origin of the Ganymede/Callisto dichotomy by impacts during an outer solar system late heavy bombardment". 41st Lunar and Planetary Science Conference (2010). Houston. http://www.lpi.usra.edu/meetings/lpsc2010/pdf/1158.pdf. Retrieved 2010-03-01. 
  74. Barr, A. C.; Canup, R. M. (2010-01-24). "Origin of the Ganymede–Callisto dichotomy by impacts during the late heavy bombardment". Nature Geoscience 3 (March 2010): 164–167. doi:10.1038/NGEO746. http://www.nature.com/ngeo/journal/v3/n3/abs/ngeo746.html. Retrieved 2010-03-01. 
  75. 75.0 75.1 Nagel, K.A; Breuer, D.; Spohn, T. (2004). "A model for the interior structure, evolution, and differentiation of Callisto". Icarus 169: 402–412. doi:10.1016/j.icarus.2003.12.019. http://adsabs.harvard.edu/abs/2004Icar..169..402N. 
  76. "USGS Astrogeology: Rotation and pole position for planetary satellites (IAU WGCCRE)". http://astrogeology.usgs.gov/Projects/WGCCRE/constants/iau2000_table2.html. 
  77. "Exploration of Ganymede". Terraformers Society of Canada. Archived from the original on 2007-03-19. http://web.archive.org/web/20070319083334/http://society.terraformers.ca/content/view/63/112/. Retrieved 2008-01-06. 
  78. "Voyager 1 and 2". ThinkQuest. http://library.thinkquest.org/J0112188/voyager_1_and_2.htm. Retrieved 2008-01-06. 
  79. "The Voyager Planetary Mission". Views of the Solar System. http://www.solarviews.com/eng/vgrfs.htm. Retrieved 2008-01-06. 
  80. "New Discoveries From Galileo". Jet Propulsion Laboratory. http://www2.jpl.nasa.gov/galileo/status961212.html. Retrieved 2008-01-06. 
  81. "Pluto-Bound New Horizons Spacecraft Gets A Boost From Jupiter". Space Daily. http://www.spacedaily.com/reports/Pluto_Bound_New_Horizons_Spacecraft_Gets_A_Boost_From_Jupiter_999.html. Retrieved 2008-01-06. 
  82. Grundy, W.M.; Buratti, B.J.; Cheng, A.F. et al. (2007). "New Horizons Mapping of Europa and Ganymede". Science 318 (5848): 234–237. doi:10.1126/science.1147623. PMID 17932288. http://adsabs.harvard.edu/abs/2007Sci...318..234G. 
  83. Rincon, Paul (2009-02-20). "Jupiter in space agencies' sights". BBC News. http://news.bbc.co.uk/1/hi/sci/tech/7897585.stm. Retrieved 2009-02-20. 
  84. "Cosmic Vision 2015–2025 Proposals". ESA. 2007-07-21. http://sci.esa.int/science-e/www/object/index.cfm?fobjectid=41177. Retrieved 2009-02-20. 
  85. "Jupiter Icy Moons Orbiter (JIMO)". The Internet Encyclopedia of Science. http://www.daviddarling.info/encyclopedia/J/JIMO.html. Retrieved 2008-01-06. 
  86. "Jupiter Icy Moons Orbiter Victim of Budget Cut". Planet Surveyor. http://www.planetsurveyor.com/latest-space-exploration-news/jupiter-icy-moons-orbiter-victim-of-budget-cut.html. Retrieved 2008-01-06. 

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