Natural satellite
From Wikipedia, the free encyclopedia
A natural satellite or moon is an celestial body that orbits another celestial body, planet or smaller, which is called the primary. Technically, the term natural satellite could refer to a planet orbiting a star, or a dwarf galaxy orbiting a major galaxy, but it is normally synonymous with moon and used to identify non-artificial satellites of planets, dwarf planets, and minor planets. (There are no known natural satellites of moons.)
240 bodies, all in the Solar System, are classified as moons. They include 166 orbiting the eight planets,[1] 4 orbiting dwarf planets, and dozens more orbiting small solar system bodies. Other stars and their planets are very likely to have natural satellites, although none have yet been observed.
The large gas giants have extensive systems of moons, including half a dozen comparable in size to Earth's moon: the four Galilean moons, Saturn's Titan, and Neptune's Triton. Saturn has an additional six mid-sized moons massive enough to have achieved hydrostatic equilibrium, Uranus has five, and Pluto one. Of the inner planets, Mercury and Venus have no moons at all; Earth has one large moon (the Moon); and Mars has two tiny moons, Phobos and Deimos. Among the dwarf planets, Ceres has no moons (though many objects in the asteroid belt do), Eris has one, Dysnomia, and Pluto has three known satellites, Nix, Hydra, and a large companion called Charon. The Pluto-Charon system is unusual in that the center of mass lies in open space between the two, a characteristic of a double planet system.
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[edit] Limits of what is a 'moon'
There is no established lower limit on what should be considered a moon: Every satellite with an identified orbit, some as small as a kilometer across, has been identified as a moon, though clumps a tenth that size within Saturn's rings (which may not be solid bodies) have been called moonlets. (Small asteroid moons, such as Dactyl, some up to tens of kilometers across, have also been called moonlets.) The upper limit is also vague: When the masses of two orbiting bodies are similar enough that one cannot be said to orbit the other, they are described as a dual body rather than primary and satellite. However, with the exception of Pluto-Charon among some authors, only asteroids are such as 90 Antiope are considered dual bodies, and they have not yet forced a clear definition as to what constitutes a moon.
[edit] Origin
The natural satellites orbiting relatively close to the planet on prograde orbits (regular satellites) are generally believed to have been formed out of the same collapsing region of the protoplanetary disk that gave rise to its primary. In contrast, irregular satellites (generally orbiting on distant, inclined, eccentric and/or retrograde orbits) are thought to be captured asteroids possibly further fragmented by collisions. The Earth-Moon[2] and possibly Pluto-Charon systems[3] are exceptions among large bodies in that they are believed to have originated by the collision of two large proto-planetary objects (see the giant impact hypothesis). The material that would have been placed in orbit around the central body is predicted to have reaccreted to form one or more orbiting moons. As opposed to planetary-sized bodies, asteroid moons are thought to commonly form by this process.
[edit] Orbital characteristics
[edit] Tidal locking
Most regular natural satellites in the solar system are tidally locked to their primaries, meaning that one side of the moon is always turned toward the planet. Exceptions include Saturn's moon Hyperion, which rotates chaotically because of a variety of external influences.
In contrast, the outer moons of the gas giants (irregular satellites) are too far away to become 'locked'. For example, Jupiter's moon Himalia, Saturn's moon Phoebe and Neptune's moon Nereid have rotation period in the range of 10 hours compared with their orbital periods of hundreds of days.
[edit] Satellites of satellites
No "moons of moons" (natural satellites that orbit the natural satellite of another body) are known. It is uncertain whether such objects can be stable in the long term. In most cases, the tidal effects of their primaries make such a system unstable; the gravity from other nearby objects (most notably the primary) would perturb the orbit of the moon's moon until it broke away or impacted its primary. In theory, a secondary satellite could exist in a primary satellite's Hill sphere, outside of which it would be lost because of the greater gravitational pull of the planet (or other object) that the primary satellite orbits. For example, the Moon orbits Earth because the Moon is 370,000 km from Earth, well within Earth's Hill sphere, which has a radius of 1.5 million km (0.01 AU or 235 Earth radii). If a Moon-sized object were to orbit Earth outside its Hill sphere, it would soon be captured by the Sun and become a dwarf planet in a near-Earth orbit.
[edit] Trojan satellites
Two moons are known to have small companions at their L4 and L5 Lagrangian points, which are about sixty degrees ahead of and behind the body in its orbit. These companions are called Trojan moons, because their positions are comparable to the positions of the Trojan asteroids relative to Jupiter. Such objects are Telesto and Calypso, which are the leading and following companions respectively of Tethys; and Helene and Polydeuces, which are the leading and following companions of Dione.
[edit] Asteroid satellites
The discovery of 243 Ida's moon Dactyl in the early 1990s confirms that some asteroids also have moons. Some, like 90 Antiope, are double asteroids with two equal-sized components. The asteroid 87 Sylvia has two moons. See asteroid moon for further information.
[edit] Natural satellites of the Solar System
The largest natural satellites in the Solar System (those bigger than about 3000 km across) are Earth's moon, Jupiter's Galilean moons (Io, Europa, Ganymede, and Callisto), Saturn's moon Titan, and Neptune's captured moon Triton. For smaller moons see the articles on the appropriate planet. In addition to the moons of the various planets there are also over 80 known moons of the dwarf planets, asteroids and other small solar system bodies. Some studies estimate that up to 15% of all trans-Neptunian objects could have satellites.
The following is a comparative table classifying the moons of the solar system by diameter. The column on the right includes some notable planets, dwarf planets, asteroids, and Trans-Neptunian Objects for comparison. It is normal for natural satellites to be named after mythological figures, (predominately Greek), however Uranus's moons are named after Shakespearean characters. Bodies massive enough to have achieved hydrostatic equilibrium are in bold. Those suspected but not proven to have achieved a hydrostatic equilibrium are italicized.
[edit] Terminology
The first known natural satellite was the Moon (luna in Latin). Until the discovery of the Galilean satellites in 1610, however, there was no opportunity for referring to such objects as a class. Galileo chose to refer to his discoveries as Planetæ ("planets"), but later discoverers chose other terms to distinguish them from the objects they orbited.
Christiaan Huygens, the discoverer of Titan, was the first to use the term moon for such objects, calling Titan Luna Saturni or Luna Saturnia – "Saturn's moon" or "The Saturnian moon", because it stood in the same relation to Saturn as the Moon did to the Earth.
As additional moons of Saturn were discovered, however, this term was abandoned. Giovanni Domenico Cassini sometimes referred to his discoveries as planètes in French, but more often as satellites, using a term derived from the Latin satelles, meaning "guard", "attendant", or "companion", because the satellites accompanied their primary planet in their journey through the heavens.
The term satellite thus became the normal one for referring to an object orbiting a planet, as it avoided the ambiguity of "moon". In 1957, however, the launching of the artificial object Sputnik created a need for new terminology. The terms man-made satellite or artificial moon were very quickly abandoned in favor of the simpler satellite, and as a consequence, the term has come to be linked primarily with artificial objects flown in space – including, sometimes, even those which are not in orbit around a planet.
As a consequence of this shift in meaning, the term moon, which had continued to be used in a generic sense in works of popular science and in fiction, has regained respectability and is now used interchangeably with satellite, even in scientific articles. When it is necessary to avoid both the ambiguity of confusion with the Earth's moon on the one hand, and artificial satellites on the other, the term natural satellite (using "natural" in a sense opposed to "artificial") is used.
[edit] The definition of a moon
There has been some debate about the precise definition of a moon. This debate has been caused by the presence of orbital systems where the difference in mass between the larger body and its satellite is not as pronounced as in more typical systems. Two examples are the Pluto-Charon system and the Earth-Moon System. The presence of these systems has caused a debate about where to precisely draw the line between a double body system, and a main body-satellite system. The most common definition rests upon whether the barycentre is below the surface of the larger body, though this is unofficial and somewhat arbitrary. At the other end of the spectrum there are many ice/rock clumps that form ring systems around the Solar System's gas giants, and there is no set point to define when one of these clumps is large enough to be classified as a moon. The term "moonlet" is sometimes used to refer to extremely small objects in orbit around a larger body, but again there is no official definition.
The smallest extra-Solar objects so far found to have satellites are brown dwarfs and sub-brown dwarfs; their satellites are considered planets rather than moons.
[edit] See also
- Co-orbital moon
- Extrasolar moon
- Inner moon
- Irregular moon
- List of moons
- List of moons by diameter
- Naming of moons
- Quasi-satellite
- Timeline of discovery of Solar System planets and their moons
- Trojan moon
[edit] Moons of planets
[edit] Moons of dwarf planets and small Solar System bodies
[edit] Notes and references
- ^ List of natural satellites orbiting the planets.
- ^ R. Canup and E. Asphaug (2001). "Origin of the Moon in a giant impact near the end of the Earth's formation". Nature 412: 708-712.
- ^ S. Stern, H. Weaver, A. Steffl, M. Mutchler, W. Merline, M. Buie, E. Young, L. Young, and J. Spencer (2006). "A giant impact origin for Pluto's small moons and satellite multiplicity in the Kuiper belt". Nature 439: 946-949.
[edit] External links
[edit] Jupiter's moons
- Data on Jupiter's satellites
- Jupiter's new moons (discovered in 2000)
- Jupiter's new moons (discovered in 2002)
- Jupiter's new moons (discovered in 2003)
[edit] Saturn's moons
[edit] All moons
- Natural Satellite Physical Parameters (JPL-NASA, with refs)
- Moons of the Solar System (The Planetary Society)
- Scott Sheppard's page
- Major moons in order from the Sun
- JPL's Solar System Dynamics page
- Moon of an Object? First Photo of Satellite Beyond the Solar System
- USGS list of named moons
- Upper size limit for moons explained
- Asteroids with Satellites
| The Solar System |
|---|
| <imagemap>
Image:Solar System XXVII.png
circle 0 0 90 35 The Sun
circle 112 18 6 Mercury
circle 153 18 8 Venus
circle 203 8 4 The Moon circle 194 18 8 Earth
circle 239 13 3 Phobos and Deimos circle 233 18 8 Mars
circle 271 18 8 Ceres rect 256 0 288 35 The asteroid belt
circle 316 18 15 Jupiter circle 329 5 6 Moons of Jupiter
circle 372 18 10 Saturn circle 381 7 6 Moons of Saturn
circle 418 18 9 Uranus circle 427 10 6 Moons of Uranus
circle 471 10 3 Moons of Neptune circle 462 18 12 Neptune
circle 508 13 3 Moons of Pluto circle 504 18 8 Pluto rect 492 0 527 35 The Kuiper Belt
circle 544 14 3 Dysnomia circle 540 18 8 Eris rect 528 0 567 35 The Scattered Disc rect 568 0 597 35 The Oort Cloud desc none
</imagemap> |
| The Sun · Mercury · Venus · Earth · Mars · Ceres · Jupiter · Saturn · Uranus · Neptune · Pluto · Eris |
| Planets · Dwarf planets · Moons: Terrestrial · Martian · Jovian · Saturnian · Uranian · Neptunian · Plutonian · Eridian |
| Small bodies: Meteoroids · Asteroids/Asteroid moons (Asteroid belt) · Centaurs · TNOs (Kuiper belt/Scattered disc) · Comets (Oort cloud) |
| See also astronomical objects, the solar system's list of objects, sorted by radius or mass, and the Solar System Portal |
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