Planet
|
Artists' concept of a gas giant planet in orbit around the triple-star system HD 188753, as seen from a hypothetical moon. NASA image |
A
planet is generally considered to be a relatively large mass of accreted matter in
orbit around a
star. A mass that becomes massive enough to undergo nuclear reactions is considered a
star, not a planet. Based on historical consensus, the
International Astronomical Union (IAU) lists nine planets in our
solar system. However, since the term "planet" has no precise scientific definition, many astronomers contest that figure. Some say it should be lowered to eight by removing
Pluto from the list, while others claim it should be raised to ten or even higher depending on how planets are categorized.
It is not known with certainty how planets are formed. The prevailing theory is that they are formed from those remnants of a
nebula that do not condense under
gravity to form a
protostar. Instead, these remnants become a thin,
protoplanetary disk of dust and gas revolving around the protostar and begin to condense about local concentrations of mass within the disc known as
planetesimals. These concentrations become ever more dense until they collapse inward under gravity to form
protoplanets.
After a planet reaches a diameter larger than the Earth's moon, it begins to accumulate an extended atmosphere. This serves to increase the capture rate of the planetesimals by a factor of ten.
When the protostar has grown such that it ignites to form a
star, its
solar wind blows away most of the disc's remaining material. Thereafter there still may be many protoplanets orbiting the star or each other, but over time many will collide, either to form a single larger planet or release material for other larger protoplanets or planets to absorb.
Meanwhile, protoplanets that have avoided collisions may become
natural satellites of larger planets through a process of gravitational capture.
The energetic impacts of the smaller planetesimals will heat up the growing planet, causing it to at least partially melt. The interior of the planet begins to differentiate by mass, developing a denser core. Smaller terrestrial planets lose most of their atmospheres due to this accretion, but the lost gases can be replaced by outgassing from the mantle and from the subsequent impact of
comets.
(Note that smaller planets will lose any atmosphere they gain through various
escape mechanisms.)
With the discovery and observation of planetary systems around stars other than our own, it is becoming possible to elaborate, revise or even replace this account.
The name "planet" comes from the
ancient Greek term πλανήτης,
planÄ"tÄ"s, meaning "wanderer", as ancient astronomers noted how certain lights moved across the sky in relation to the other stars. These objects were believed to orbit the
Earth, which was considered stationary.
The original number of planets was seven:
Moon,
Mercury,
Venus,
Sun,
Mars,
Jupiter, and
Saturn, in orbit order outwards according to the
Ptolemaic system.
Some
Romans believed that the seven gods that the planets were named after, took hourly shifts in looking after affairs on Earth, in Ptolemaic orbit order listed inwards (the reverse of the above list). As a result, a list of which god has charge of the first hour in each day, comes out as Sun, Moon, Mars, Mercury, Jupiter, Venus, Saturn, i.e. the usual weekday name order: Sunday, Mo(o)nday,
French mardi, mercredi, jeudi, vendredi, Satur(n)day.
notes about days of the
week: "The seven-day system we use is based on the ancient astrological notion that the seven known celestial bodies influence what happens on Earth and that each of these celestial bodies controls the first hour of the day named after it. This system was brought into
Hellenistic Egypt from
Mesopotamia".
Developments in
Astronomy, in particular the acceptance of the
heliocentric model, removed the Sun and the Moon, and added the currently accepted planetary members of the Solar System.
The process of naming planets and their features is known as
planetary nomenclature. All the currently accepted planets in the
solar system are named after
Roman gods, except for
Uranus (named after a
Greek god) and the
Earth, which was not seen as a planet by the ancients but rather the centre of the universe.
The designated planetary names are near-universal in the
Western world, but some non-European languages use their own. China, and the countries of eastern Asia subject to Chinese cultural influence, use a naming system based on the
five Chinese elements .
A
western exception is, naturally,
Greece which uses the equivalent Greek gods' names:
Hermes (Mercury),
Aphrodite (Venus),
Gaia (Earth),
Ares (Mars),
Zeus (Jupiter),
Cronus (Saturn),
Ouranos (Uranus),
Poseidon (Neptune),
Pluton—not the expected
Hades—(Pluto).
Moons are also named after gods and characters from classical mythology, or, in the case of Uranus, after characters from English literature.
Asteroids can be named after anybody or anything at the discretion of their discoverers, subject to approval by the IAU's nomenclature panel.
|
The nine planets of our solar system, minus Pluto, plus the Moon (sizes and distances not to scale; Pluto is not present because no close up images have been taken of it yet) |
According to the
IAU, there are nine planets in our solar system. In increasing distance from the
Sun they are (with the
astronomical symbol in brackets and their
natural satellites):#
Mercury ()#
Venus ()#
Earth () with one confirmed natural satellite,
Luna (the
Moon)#
Mars () with two confirmed natural satellites,
Phobos and
Deimos#
Jupiter () with
sixty-three confirmed natural satellites#
Saturn () with
fifty-six confirmed natural satellites#
Uranus (
|
Astronomical symbol for Uranus |
) with
twenty-seven confirmed natural satellites#
Neptune () with
thirteen confirmed natural satellites#
Pluto () with three confirmed natural satellites,
Charon,
Nix and
HydraHowever, there is some pressure for
Pluto to be reclassified as a
Kuiper Belt object, especially in light of the discovery of (temporarily nicknamed "Xena"). This object, however, has not yet received a definitive classification from the IAU. In order to put these matters to rest, the
IAU plans to publish an official
definition of "planet" in early September 2006, ruling on whether to call Pluto a planet or a
Kuiper Belt Object (KBO).
align=bottom style="text-align:left;"|** See Earth article for absolute values.
| Planet | Equator*diam. | Mass* | Orbital
radius* (AU) | Orbital period*(years) | Orbital
Incline Angle (°) | Orbital
Eccentricity | Day*(days)! Moons |
|---|
| Mercury | 0.382 | 0.06 | 0.387 | 0.241 | 7.00 | 0.206 | 58.6 | none |
| Venus | 0.949 | 0.82 | 0.72 | 0.615 | 3.39 | 0.0068 | -243 | none |
| Earth** | 1.00 | 1.00 | 1.00 | 1.00 | 0.00 | 0.0167 | 1.00 | 1 |
| Mars | 0.53 | 0.11 | 1.52 | 1.88 | 1.85 | 0.0934 | 1.03 | 2 |
| Jupiter | 11.2 | 318 | 5.20 | 11.86 | 1.31 | 0.0484 | 0.414 | 63 |
| Saturn | 9.41 | 95 | 9.54 | 29.46 | 2.48 | 0.0542 | 0.426 | 56 |
| Uranus | 3.98 | 14.6 | 19.22 | 84.01 | 0.77 | 0.0472 | -0.718 | 27 |
| Neptune | 3.81 | 17.2 | 30.06 | 164.8 | 1.77 | 0.0086 | 0.671 | 13 |
| Pluto | 0.18 | 0.002 | 39.5 | 248.5 | 17.1 | 0.249 | -6.5 | 3 |
Other candidates
When
Ceres was found orbiting between
Mars and
Jupiter in
1801, it was initially touted as a planet, but after many smaller objects were found with a similar orbit, it was classified as an
asteroid. However, due to its large size (relative to the other asteroids), and its roughly spherical shape, Ceres would be considered a planet by some astronomers' definitions.
Similarly, since
1992 many objects have been found in the predicted
Kuiper Belt that exists beyond Neptune. Several of the largest of these have challenged the planetary status quo, as they are both spherical and larger than the bodies in the Mars–Jupiter
asteroid belt, and are similar in size, orbit and composition to
Pluto.
There is also the case of
Sedna, a body that lies beyond the Kuiper Belt and is often thought to be the only observed member of the
Oort Cloud. Like Ceres before it, Sedna was widely touted as a planet when it was discovered in
2003, as it was the largest object found since Pluto. However, mainly due to its size still being smaller than Pluto's, it also did not achieve planetary status from the IAU.
So far none of these objects have been accepted as planets by the
IAU. However, the discovery in
2005 of , with a size and mass larger than Pluto seems to have forced the issue. It has not yet been accepted as a planet, but the IAU is expected to announce a
definition of a planet at their annual conference in
September,
2006, which will likely either see become a planet, or have Pluto stripped of its status. The latter option would appear unlikely as the IAU said in 1999 that have no plans to 'demote' Pluto, and based on the President's recent remarks and the unpopularity of such a decision, this is likely to remain the case.
Potential planetary candidates include (in order of increasing distance from the Sun):
*Ceres
*Orcus
*Ixion
*2002 UX25
*Varuna
*2002 TX200
*1996 TO66
*2003 EL61
*Quaoar
*2005 FY9
*2002 AW197
*2002 TC302
*2003 UB313- Sedna
Main article: Extrasolar planet
.
Of the 202
extrasolar planets (those outside our solar system) discovered to date (August 2006) most have masses which are about the same or larger than Jupiter's.
Exceptions include a number of planets discovered orbiting burned-out star remnants called
pulsars, such as
PSR B1257+12,
the planets orbiting the stars
Mu Arae,
55 Cancri and
GJ 436 which are approximately Neptune-sized,
and a planet orbiting
Gliese 876 that is estimated to be about 6 to 8 times as massive as the Earth and is probably rocky in composition.
It is far from clear if the newly discovered large planets would resemble the gas giants in our solar system or if they are of an entirely different type as yet unknown, like ammonia giants or carbon planets. In particular, some of the newly discovered planets, known as
hot Jupiters, orbit extremely close to their parent stars, in nearly circular orbits. They therefore receive much more
stellar radiation than the gas giants in our solar system, which makes it questionable whether they are the same type of planet at all. There is also a class of hot Jupiters that orbit so close to their star that their atmospheres are slowly blown away in a comet-like tail: the
Chthonian planets.
Several projects have been proposed to create an array of
space telescopes to search for extrasolar planets with masses comparable to the Earth. The
NASA Terrestrial Planet Finder was one such program, but (as of 2006-02-06) this program has been put on indefinite hold. The
ESA is considering a comparable mission called
Darwin. The frequency of occurance of such terrestrial planets is one of the variables in the
Drake equation which estimates the number of
intelligent, communicating civilizations that exist in our galaxy.
In 2005, astronomers
detected a planet in a
triple star system, a finding that challenges current theories of planetary formation. The planet, a gas giant slightly larger than Jupiter, orbits the main star of the
HD 188753 system, in the constellation
Cygnus, and is hence known as
HD 188753 Ab. The stellar trio (yellow, orange, and red) is about 149 light-years from Earth. The planet, which is at least 14% larger than Jupiter, orbits the main star (HD 188753 A) once every 80 hours or so (3.3 days), at a distance of about 8 Gm, a twentieth of the distance between Earth and the Sun. The other two stars whirl tightly around each other in 156 days, and circle the main star every 25.7 years at a distance from the main star that would put them between Saturn and Uranus in our own Solar System. The latter stars invalidate the leading hot Jupiter formation theory, which holds these planets form at "normal" distances and then migrate inward through some debatable mechanism. This could not have occurred here, the outer star pair disrupting outer planet formation.
Interstellar planets
Interstellar planets are rogues in interstellar space, not gravitationally linked to any given solar system. No interstellar planet is known to date, but their existence is considered a likely hypothesis based on
computer simulations of the origin and evolution of planetary systems, which often include the ejection of bodies of significant mass.
Much like "
continent", "planet" is a word without a precise definition, with
history and
culture playing as much of a role as
geology and
astrophysics. Recent definitions have been vague and imprecise;
The American Heritage Dictionary, for instance, formerly defined a planet as:
''A nonluminous celestial body larger than an asteroid or comet, illuminated by light from a star, such as the Sun, around which it revolves. In the solar system there are nine known planets: Mercury, Venus, Earth, Mars, Jupiter, Saturn, Uranus, Neptune, and Pluto.'
However, for some time that definition has been viewed by many as inadequate. The eight largest planets are universally recognised as such (although
Jupiter,
Saturn and
Neptune are not strictly nonlumious since they emit more radiation than they receive from the
Sun), and for this reason are often universally referred to as "major planets", but there is controversy over Pluto and other smaller objects.
Suggested wide definitions
Since the discoveries of many of the objects in the
Kuiper belt and around other stars, there has been a concerted push amongst scientists to come up with a precise definition of what constitutes a planet. In
1999, the IAU set up a
working group to develop a scientifically plausible recommendation,
but as of August 2005 they had not reached a conclusion. After the discovery of (informally called "Xena"), a member of the committee,
Alan Stern, has said that the group wanted "to get something done, pronto." He also informed journalists that a "consensus" in the group was moving towards the following definition:
A planet is a body that directly orbits a star, is large enough to be round because of self gravity, and is not so large that it triggers nuclear fusion in its interior.Note that this definition also covers disputes at the upper end of a planet's size, which provides the extra benefit of forming a barrier between planets and
brown dwarfs. Many consider this definition the best option as it sets up divisions based on physical characteristics rather than an arbitrary size limit. It is also somewhat universal in its application where other definitions have been crafted mainly to sort our own
solar system into simple categories (such as placing the size limit as just under
Mars,
Mercury or
Pluto). Depending how it is interpreted, objects counted as planets under such a new system would include some or all of the objects listed above, with potentially many more yet to be found.
Gibor Basri, professor of astronomy at the
University of California, Berkeley, has suggested a similar definition and has also proposed the terms "
fusor" (any object that achieves fusion in its core) and "
planemo" (an object that is round from self-gravity but not a fusor) to help improve the
astronomical nomenclature. Under Basri's definition:
A planet is a planemo orbiting a fusorThese definitions have the advantage of creating a group including larger moons (which share many characteristics with the smaller planets) and also covering
large free-roaming objects, which some astronomers think should be included in the definition of a planet. Basri has also suggested 'liberal use of adjectives' such as "major", "beltway", "dwarf", "giant", "super" and "historical".
Others have suggested categories of planet/planemo based on composition such as "rock" (composed mainly of silicate), "gas" (composed mainly of hydrogen and helium), and "ice" (composed mainly of oxygen and carbon).
Suggested narrow definitions
There are alternate suggestions which would instead
reduce the number of planets in the system. Upon his discovery of
Sedna,
Mike Brown of
Caltech suggested a definition which would exclude both Sedna and Pluto from being classified as planets, proposing the following:
A planet is any body in the solar system that is more massive than the total mass of all of the other bodies in a similar orbitThis definition generally plays down the importance of size, but instead focuses on the formation of the proposed planet. Under this definition, no
Kuiper Belt objects (including Pluto) would be considered planets.
Brown's wish to "demote" Pluto prompted many to criticize him for setting out to create a purely scientific definition for a term which had an existing popular (albeit 'flawed') application. Upon his discovery of , Brown indicated he had become a convert to this way of thinking, and proposed that whatever definition of planet be adopted, it should include both Pluto and any
Kuiper Belt object found to be larger than Pluto.
Further categories
Astronomers distinguish between
minor planets, such as
asteroids,
comets, and
trans-Neptunian objects; and major (or true) planets.
Planets within Earth's solar system can be divided into categories according to composition.
*
Terrestrial or rocky: Planets that are similar to
Earth — with bodies largely composed of
rock: Mercury, Venus, Earth, Mars
*
Jovian or
gas giant: Those with a composition largely made up of
gaseous material: Jupiter, Saturn, Uranus, Neptune. Uranian planets, or
ice giants, are a sub-class of gas giants, distinguished from true Jovians by their depletion in hydrogen and helium and a significant composition of rock and ice.
*
Icy: Sometimes a third category is added to include bodies like
Pluto, whose composition is primarily
ice; this category of "icy" bodies also includes many non-planetary bodies such as the icy
moons of the outer planets of our solar system (e.g.
Triton).
Many consider the Earth and its
Moon to be a
double planet, also called
binary planet, for several reasons:
*The
Moon, as measured by its diameter, is 1.5 times larger than Pluto.
*The gravitational force of the Sun on the Moon is larger than the gravitational force of the Earth on the Moon by a factor of approx. 2.2. (This is not a unique situation in the solar system. The Sun's gravity is also stronger than the primary's on Jupiter's moon
S/2003 J 2; Uranus' moon
S/2001 U 2; Neptune's moons
S/2002 N 4 and
Psamathe; and several
asteroid moons. However,
Luna is the sole case of this phenomenon affecting an
object of planetary mass.)
The
Pluto-
Charon system has been considered to be a
double planet because the mass ratio between these two bodies is small (about 8.6). So much so, that they both orbit a common centre of mass which lies beyond Pluto's surface, and are therefore said to orbit each other. Whereas, the centre of gravity of the Moon and Earth is within Earth itself, so the Moon is said to orbit the Earth, thereby, for some, ruling it out as a planet.
*
Definition of planet*
Planetary habitability*
Planetary science*
hypothetical planets*
Landings on other planets*
Planemo*
Planetoid*
Brown Dwarf*
Planets in science fiction*
Planets in astrology*
Prograde and retrograde motion*
Skies of other planets*
PlanetQuest*
Navagraha
*
*
*
NinePlanets.org - tour of the solar system
*
International Astronomical Union*
Solar System Live (an interactive
orrery)
*
Solar System Viewer (animation)
*
Pictures of the solar system*
Renderings of the planets*
NASA Planet Quest*
Working definition of "planet" from
IAU WGESP — the lower bound remained a matter of consensus in
February 2003*Dan Green's page on
planet classification*
Gravity Rules: The Nature and Meaning of Planethood; S. Alan Stern;
March 22,
2004*
On the status of Pluto;
IAU,
February 3,
1999*
Planets A website on Planets aimed for kids.
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