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Planet

January 20, 2023

This article is about the astronomical object. For other uses, see Planet (disambiguation).

The eight known planets of the Solar System, according to the IAU definition:
Mercury, Venus, Earth, and Mars
Jupiter and Saturn (gas giants)
Uranus and Neptune (ice giants)

Shown in order from the Sun and in true color. Sizes are not to scale.

A planet is a large, rounded astronomical body that is neither a star nor its remnant. The best available theory of planet formation is the nebular hypothesis, which posits that an interstellar cloud collapses out of a nebula to create a young protostar orbited by a protoplanetary disk. Planets grow in this disk by the gradual accumulation of material driven by gravity, a process called accretion. The Solar System has at least eight planets: the terrestrial planets Mercury, Venus, Earth and Mars, and the giant planets Jupiter, Saturn, Uranus and Neptune. These planets each rotate around an axis tilted with respect to its orbital pole. All of them possess an atmosphere, although that of Mercury is tenuous, and some share such features as ice caps, seasons, volcanism, hurricanes, tectonics, and even hydrology. Apart from Venus and Mars, the Solar System planets generate magnetic fields, and all except Venus and Mercury have natural satellites. The giant planets bear planetary rings, the most prominent being those of Saturn.

The word planet probably comes from the Greek planḗtai, meaning "wanderers". In antiquity, this word referred to the Sun, Moon, and five points of light visible by the naked eye that moved across the background of the stars—namely, Mercury, Venus, Mars, Jupiter and Saturn. Planets have historically had religious associations: multiple cultures identified celestial bodies with gods, and these connections with mythology and folklore persist in the schemes for naming newly discovered Solar System bodies. Earth itself was recognized as a planet when heliocentrism supplanted geocentrism during the 16th and 17th centuries.

With the development of the telescope, the meaning of planet broadened to include objects only visible with assistance: the ice giants Uranus and Neptune; Ceres and other bodies later recognized to be part of the asteroid belt; and Pluto, later found to be the largest member of the collection of icy bodies known as the Kuiper belt. The discovery of other large objects in the Kuiper belt, particularly Eris, spurred debate about how exactly to define a planet. The International Astronomical Union (IAU) adopted a standard by which the four terrestrials and four giants qualify, placing Ceres, Pluto and Eris in the category of dwarf planet,[1][2][3] although many planetary scientists have continued to apply the term planet more broadly.[4]

Further advances in astronomy led to the discovery of over five thousand planets outside the Solar System, termed exoplanets. These include hot Jupiters—giant planets that orbit close to their parent stars—like 51 Pegasi b, super-Earths like Gliese 581c that have masses in between that of Earth and Neptune; and planets smaller than Earth, like Kepler-20e. Multiple exoplanets have been found to orbit in the habitable zones of their stars, but Earth remains the only planet known to support life.

History

Further information: History of astronomy and Timeline of Solar System astronomy
 
1660 illustration of Claudius Ptolemy's geocentric model

The idea of planets has evolved over its history, from the divine lights of antiquity to the earthly objects of the scientific age. The concept has expanded to include worlds not only in the Solar System, but in multitudes of other extrasolar systems. The consensus definition as to what counts as a planet vs. other objects orbiting the Sun has changed several times, previously encompassing asteroids, moons, and dwarf planets like Pluto,[5][6][7] and there continues to be some disagreement today.[7]

The five classical planets of the Solar System, being visible to the naked eye, have been known since ancient times and have had a significant impact on mythology, religious cosmology, and ancient astronomy. In ancient times, astronomers noted how certain lights moved across the sky, as opposed to the "fixed stars", which maintained a constant relative position in the sky.[8] Ancient Greeks called these lights πλάνητες ἀστέρες (planētes asteres, "wandering stars") or simply πλανῆται (planētai, "wanderers"),[9] from which today's word "planet" was derived.[10][11][12] In ancient Greece, China, Babylon, and indeed all pre-modern civilizations,[13][14] it was almost universally believed that Earth was the center of the Universe and that all the "planets" circled Earth. The reasons for this perception were that stars and planets appeared to revolve around Earth each day[15] and the apparently common-sense perceptions that Earth was solid and stable and that it was not moving but at rest.[16]

Babylon

Main article: Babylonian astronomy

The first civilization known to have a functional theory of the planets were the Babylonians, who lived in Mesopotamia in the first and second millennia BC. The oldest surviving planetary astronomical text is the Babylonian Venus tablet of Ammisaduqa, a 7th-century BC copy of a list of observations of the motions of the planet Venus, that probably dates as early as the second millennium BC.[17] The MUL.APIN is a pair of cuneiform tablets dating from the 7th century BC that lays out the motions of the Sun, Moon, and planets over the course of the year.[18] Late Babylonian astronomy is the origin of Western astronomy and indeed all Western efforts in the exact sciences.[19] The Enuma anu enlil, written during the Neo-Assyrian period in the 7th century BC,[20] comprises a list of omens and their relationships with various celestial phenomena including the motions of the planets.[21][22] Venus, Mercury, and the outer planets Mars, Jupiter, and Saturn were all identified by Babylonian astronomers. These would remain the only known planets until the invention of the telescope in early modern times.[23]

Greco-Roman astronomy

See also: Greek astronomy

The ancient Greeks initially did not attach as much significance to the planets as the Babylonians. The Pythagoreans, in the 6th and 5th centuries BC appear to have developed their own independent planetary theory, which consisted of the Earth, Sun, Moon, and planets revolving around a "Central Fire" at the center of the Universe. Pythagoras or Parmenides is said to have been the first to identify the evening star (Hesperos) and morning star (Phosphoros) as one and the same (Aphrodite, Greek corresponding to Latin Venus),[24] though this had long been known in Mesopotamia.[25][26] In the 3rd century BC, Aristarchus of Samos proposed a heliocentric system, according to which Earth and the planets revolved around the Sun. The geocentric system remained dominant until the Scientific Revolution.[16]

By the 1st century BC, during the Hellenistic period, the Greeks had begun to develop their own mathematical schemes for predicting the positions of the planets. These schemes, which were based on geometry rather than the arithmetic of the Babylonians, would eventually eclipse the Babylonians' theories in complexity and comprehensiveness, and account for most of the astronomical movements observed from Earth with the naked eye. These theories would reach their fullest expression in the Almagest written by Ptolemy in the 2nd century CE. So complete was the domination of Ptolemy's model that it superseded all previous works on astronomy and remained the definitive astronomical text in the Western world for 13 centuries.[17][27] To the Greeks and Romans there were seven known planets, each presumed to be circling Earth according to the complex laws laid out by Ptolemy. They were, in increasing order from Earth (in Ptolemy's order and using modern names): the Moon, Mercury, Venus, the Sun, Mars, Jupiter, and Saturn.[12][27][28]

Medieval astronomy

Main articles: Astronomy in the medieval Islamic world and Indian astronomy

After the fall of the Western Roman Empire, astronomy developed further in India and the medieval Islamic world. In 499 CE, the Indian astronomer Aryabhata propounded a planetary model that explicitly incorporated Earth's rotation about its axis, which he explains as the cause of what appears to be an apparent westward motion of the stars. He also theorised that the orbits of planets were elliptical.[29] Aryabhata's followers were particularly strong in South India, where his principles of the diurnal rotation of Earth, among others, were followed and a number of secondary works were based on them.[30]

The astronomy of the Islamic Golden Age mostly took place in the Middle East, Central Asia, Al-Andalus, and North Africa, and later in the Far East and India. These astronomers, like the polymath Ibn al-Haytham, generally accepted geocentrism, although they did dispute Ptolemy's system of epicycles and sought alternatives. The 10th-century astronomer Abu Sa'id al-Sijzi accepted that the Earth rotates around its axis.[31] In the 11th century, the transit of Venus was observed by Avicenna.[32] His contemporary Al-Biruni devised a method of determining the Earth's radius using trigonometry that, unlike the older method of Eratosthenes, only required observations at a single mountain.[33]

Scientific Revolution and new planets

See also: Heliocentrism

With the advent of the Scientific Revolution and the heliocentric model of Copernicus, Galileo and Kepler, use of the term "planet" changed from something that moved around the sky relative to the fixed star to a body that orbited the Sun, directly (a primary planet) or indirectly (a secondary or satellite planet). Thus the Earth was added to the roster of planets[34] and the Sun was removed. The Copernican count of primary planets stood until 1781, when William Herschel discovered Uranus.[35]

When four satellites of Jupiter (the Galilean moons) and five of Saturn were discovered in the 17th century, they were thought of as "satellite planets" or "secondary planets" orbiting the primary planets, though in the following decades they would come to be called simply "satellites" for short. Scientists generally considered planetary satellites to also be planets until about the 1920s, although this usage was not common among non-scientists.[7]

In the first decade of the 19th century, four new planets were discovered: Ceres (in 1801), Pallas (in 1802), Juno (in 1804), and Vesta (in 1807). It soon became apparent that they were rather different from previously known planets: they shared the same general region of space, between Mars and Jupiter (the asteroid belt), with sometimes overlapping orbits. This was an area where only one planet had been expected, and they were much much smaller than all other planets; indeed, it was suspected that they might be shards of a larger planet that had broken up. Herschel called them asteroids (from the Greek for "starlike") because even in the largest telescopes they resembled stars, without a resolvable disk.[6][36]

The situation was stable for four decades, but in the mid-1840s several additional asteroids were discovered (Astraea in 1845, Hebe in 1847, Iris in 1847, Flora in 1848, Metis in 1848, and Hygiea in 1849), and soon new "planets" were discovered every year. As a result, astronomers began tabulating the asteroids (minor planets) separately from the major planets, and assigning them numbers instead of abstract planetary symbols,[6] although they continued to be considered as small planets.[37]

Neptune was discovered in 1846, its position having been predicted thanks to its gravitational influence upon Uranus. Because the orbit of Mercury appeared to be affected in a similar way, it was believed in the late 19th century that there might be another planet even closer to the Sun. However, the discrepancy between Mercury's orbit and the predictions of Newtonian gravity was instead explained by an improved theory of gravity, Einstein's general relativity.[38][39]

20th century

Pluto was discovered in 1930. After initial observations led to the belief that it was larger than Earth,[40] the object was immediately accepted as the ninth major planet. Further monitoring found the body was actually much smaller: in 1936, Ray Lyttleton suggested that Pluto may be an escaped satellite of Neptune,[41] and Fred Whipple suggested in 1964 that Pluto may be a comet.[42] The discovery of its large moon Charon in 1978 showed that Pluto was only 0.2% the mass of Earth.[43] As this was still substantially more massive than any known asteroid, and because no other trans-Neptunian objects had been discovered at that time, Pluto kept its planetary status, only officially losing it in 2006.[44][45]

In the 1950s, Gerard Kuiper published papers on the origin of the asteroids. He recognised that asteroids were typically not spherical, as had previously been thought, and that the asteroid families were remnants of collisions. Thus he differentiated between the largest asteroids as "true planets" versus the smaller ones as collisional fragments. From the 1960s onwards, the term "minor planet" was mostly displaced by the term "asteroid", and references to the asteroids as planets in the literature became scarce, except for the geologically evolved largest three: Ceres, and less often Pallas and Vesta.[37]

The beginning of Solar System exploration by space probes in the 1960s spurred a renewed interest in planetary science. A split in definitions regarding satellites occurred around then: planetary scientists began to reconsider the large moons as also being planets, but astronomers who were not planetary scientists generally did not.[7]

In 1992, astronomers Aleksander Wolszczan and Dale Frail announced the discovery of planets around a pulsar, PSR B1257+12.[46] This discovery is generally considered to be the first definitive detection of a planetary system around another star. Then, on 6 October 1995, Michel Mayor and Didier Queloz of the Geneva Observatory announced the first definitive detection of an exoplanet orbiting an ordinary main-sequence star (51 Pegasi).[47]

The discovery of extrasolar planets led to another ambiguity in defining a planet: the point at which a planet becomes a star. Many known extrasolar planets are many times the mass of Jupiter, approaching that of stellar objects known as brown dwarfs. Brown dwarfs are generally considered stars due to their theoretical ability to fuse deuterium, a heavier isotope of hydrogen. Although objects more massive than 75 times that of Jupiter fuse simple hydrogen, objects of 13 Jupiter masses can fuse deuterium. Deuterium is quite rare, constituting less than 0.0026% of the hydrogen in the galaxy, and most brown dwarfs would have ceased fusing deuterium long before their discovery, making them effectively indistinguishable from supermassive planets.[48]

21st century

With the discovery during the latter half of the 20th century of more objects within the Solar System and large objects around other stars, disputes arose over what should constitute a planet. There were particular disagreements over whether an object should be considered a planet if it was part of a distinct population such as a belt, or if it was large enough to generate energy by the thermonuclear fusion of deuterium.[49] Complicating the matter even further, bodies too small to generate energy by fusing deuterium can form by gas-cloud collapse just like stars and brown dwarfs, even down to the mass of Jupiter:[50] there was thus disagreement about whether how a body formed should be taken into account.[49]

A growing number of astronomers argued for Pluto to be declassified as a planet, because many similar objects approaching its size had been found in the same region of the Solar System (the Kuiper belt) during the 1990s and early 2000s. Pluto was found to be just one small body in a population of thousands.[49] They often referred to the demotion of the asteroids as a precedent, although that had been done based on their geophysical differences from planets rather than their being in a belt.[7] Some of the larger trans-Neptunian objects, such as Quaoar, Sedna, Eris, and Haumea[51] were heralded in the popular press as the tenth planet. The announcement of Eris in 2005, an object 27% more massive than Pluto, created the impetus for an official definition of a planet,[49] as considering Pluto a planet would logically have demanded that Eris be considered a planet as well. Since different procedures were in place for naming planets versus non-planets, this created an urgent situation because under the rules Eris could not be named without defining what a planet was.[7] At the time, it was also thought that the size required for a trans-Neptunian object to become round was about the same as that required for the moons of the giant planets (about 400 km diameter), a figure that would have suggested about 200 round objects in the Kuiper belt and thousands more beyond.[52][53] Many astronomers argued that the public would not accept a definition creating a large number of planets.[7]

To acknowledge the problem, the IAU set about creating the definition of planet, and produced one in August 2006. Their definition dropped to the eight significantly larger bodies that had cleared their orbit (Mercury, Venus, Earth, Mars, Jupiter, Saturn, Uranus, and Neptune), and a new class of dwarf planets was created, initially containing three objects (Ceres, Pluto and Eris).[54]

This definition has not been universally used or accepted. In planetary geology celestial objects have been assessed and defined as planets by geophysical characteristics. Planetary scientists are more interested in planetary geology than dynamics, so they classify planets based on their geological properties. A celestial body may acquire a dynamic (planetary) geology at approximately the mass required for its mantle to become plastic under its own weight. This leads to a state of hydrostatic equilibrium where the body acquires a stable, round shape, which is adopted as the hallmark of planethood by geophysical definitions. For example:[55]

a substellar-mass body that has never undergone nuclear fusion and has enough gravitation to be round due to hydrostatic equilibrium, regardless of its orbital parameters.[56]

In the Solar System, this mass is generally less than the mass required for a body to clear its orbit, and thus some objects that are considered "planets" under geophysical definitions are not considered as such under the IAU definition, such as Ceres and Pluto.[3] Proponents of such definitions often argue that location should not matter and that planethood should be defined by the intrinsic properties of an object.[3] Dwarf planets had been proposed as a category of small planet (as opposed to planetoids as sub-planetary objects) and planetary geologists continue to treat them as planets despite the IAU definition.[57]

 
The largest known trans-Neptunian objects with their moons; the Earth and Moon have been added for comparison. All pictures are artist's impressions except for the Pluto and Earth systems.

The number of dwarf planets even among known objects is not certain. In 2019, Grundy et al. argued based on the low densities of some mid-sized trans-Neptunian objects that the limiting size required for a trans-Neptunian object to reach equilibrium was in fact much larger than it is for the icy moons of the giant planets, being about 900 km diameter.[57] There is general consensus on Ceres in the asteroid belt[58] and on the eight trans-Neptunians that probably cross this threshold: Quaoar, Sedna, Orcus, Pluto, Haumea, Eris, Makemake, and Gonggong.[59] Planetary geologists may include the twenty known planetary-mass moons as "satellite planets", including Earth's Moon and Pluto's Charon, like the early modern astronomers.[3][60] Some go even further and include relatively large, geologically evolved bodies that are nonetheless not very round today, such as Pallas and Vesta,[3] or rounded bodies that were completely disrupted by impacts and re-accreted like Hygiea, as planets.[61][62][63]

The 2006 IAU definition presents some challenges for exoplanets because the language is specific to the Solar System and the criteria of roundness and orbital zone clearance are not presently observable for exoplanets.[64] There is no official definition of exoplanets, but the IAU's working group on the topic adopted a provisional statement in 2018.

Astronomer Jean-Luc Margot proposed a mathematical criterion that determines whether an object can clear its orbit during the lifetime of its host star, based on the mass of the planet, its semimajor axis, and the mass of its host star.[65] The formula produces a value called π that is greater than 1 for planets.[a] The eight known planets and all known exoplanets have π values above 100, while Ceres, Pluto, and Eris have π values of 0.1, or less. Objects with π values of 1 or more are expected to be approximately spherical, so that objects that fulfill the orbital zone clearance requirement automatically fulfill the roundness requirement.[66]

Definition and similar concepts

Main articles: Definition of planet and IAU definition of planet
 
Euler diagram showing the IAU Executive Committee conception of the types of bodies in the Solar System

At the 2006 meeting of the IAU's General Assembly, after much debate and one failed proposal, the following definition was passed in a resolution voted for by a large majority of those remaining at the meeting, addressing particularly the issue of the lower limits for a celestial object to be defined as a planet. The 2006 resolution defines planets within the Solar System as follows:[1]

A "planet" [1] is a celestial body inside the Solar System that (a) is in orbit around the Sun, (b) has sufficient mass for its self-gravity to overcome rigid body forces so that it assumes a hydrostatic equilibrium (nearly round) shape, and (c) has cleared the neighbourhood around its orbit.

[1] The eight planets are: Mercury, Venus, Earth, Mars, Jupiter, Saturn, Uranus, and Neptune.

Under this definition, the Solar System is considered to have eight planets. Bodies that fulfill the first two conditions but not the third are classified as dwarf planets, provided they are not natural satellites of other planets. Originally an IAU committee had proposed a definition that would have included a larger number of planets as it did not include (c) as a criterion.[67] After much discussion, it was decided via a vote that those bodies should instead be classified as dwarf planets.[45]

This definition is based in modern theories of planetary formation, in which planetary embryos initially clear their orbital neighborhood of other smaller objects. As described below, planets form by material accreting together in a disk of matter surrounding a protostar. This process results in a collection of relatively substantial objects, each of which has either "swept up" or scattered away most of the material that had been orbiting near it. These objects do not collide with one another because they are too far apart, sometimes in orbital resonance.[68]

Exoplanet

Main article: Exoplanet § Definition

The 2006 IAU definition presents some challenges for exoplanets because the language is specific to the Solar System and the criteria of roundness and orbital zone clearance are not presently observable for exoplanets.[64] The IAU working group on extrasolar planets (WGESP) issued a working definition in 2001 and amended it in 2003.[69] In 2018, this definition was reassessed and updated as knowledge of exoplanets increased.[69] The current official working definition of an exoplanet is as follows:[70]

  1. Objects with true masses below the limiting mass for thermonuclear fusion of deuterium (currently calculated to be 13 Jupiter masses for objects of solar metallicity) that orbit stars, brown dwarfs or stellar remnants and that have a mass ratio with the central object below the L4/L5 instability (M/Mcentral < 2/(25+621) are "planets" (no matter how they formed). The minimum mass/size required for an extrasolar object to be considered a planet should be the same as that used in our Solar System.
  2. Substellar objects with true masses above the limiting mass for thermonuclear fusion of deuterium are "brown dwarfs", no matter how they formed nor where they are located.
  3. Free-floating objects in young star clusters with masses below the limiting mass for thermonuclear fusion of deuterium are not "planets", but are "sub-brown dwarfs" (or whatever name is most appropriate).[70]

The IAU noted that this definition could be expected to evolve as knowledge improves.[70] A 2022 review article discussing the history and rationale of this definition suggested that the words "in young star clusters" should be deleted in clause 3, as such objects have now been found elsewhere, and that the term "sub-brown dwarfs" should be replaced by the more current "free-floating planetary mass objects".[69]

Planetary-mass object

Main article: Planetary-mass object
See also: List of gravitationally rounded objects of the Solar System
 
The planetary-mass moons to scale, compared with Mercury, Venus, Earth, Mars, and Pluto. Borderline Proteus and Nereid (about the same size as round Mimas) have been included. Unimaged Dysnomia (intermediate in size between Tethys and Enceladus) is not shown.

Geoscientists often reject the IAU definition, preferring to consider round moons and dwarf planets as also being planets. Some scientists who accept the IAU definition of "planet" use other terms for bodies satisfying geophysical planet definitions, such as "world".[7] The term "planetary mass object" has also been used to refer to ambiguous situations concerning exoplanets, such as objects with mass typical for a planet that are free-floating or orbit a brown dwarf instead of a star.[69]

Mythology and naming

See also: Weekday names and classical planet

The names for the planets in the Western world are derived from the naming practices of the Romans, which ultimately derive from those of the Greeks and the Babylonians. In ancient Greece, the two great luminaries the Sun and the Moon were called Helios and Selene, two ancient Titanic deities; the slowest planet (Saturn) was called Phainon, the shiner; followed by Phaethon (Jupiter), "bright"; the red planet (Mars) was known as Pyroeis, the "fiery"; the brightest (Venus) was known as Phosphoros, the light bringer; and the fleeting final planet (Mercury) was called Stilbon, the gleamer. The Greeks assigned each planet to one among their pantheon of gods, the Olympians and the earlier Titans:[17]

  • Helios and Selene were the names of both planets and gods, both of them Titans (later supplanted by Olympians Apollo and Artemis);
  • Phainon was sacred to Cronus, the Titan who fathered the Olympians;
  • Phaethon was sacred to Zeus, Cronus's son who deposed him as king;
  • Pyroeis was given to Ares, son of Zeus and god of war;
  • Phosphoros was ruled by Aphrodite, the goddess of love; and
  • Stilbon with its speedy motion, was ruled over by Hermes, messenger of the gods and god of learning and wit.[17]

The Greek practice of grafting their gods' names onto the planets was almost certainly borrowed from the Babylonians. The Babylonians named Venus after their goddess of love, Ishtar; Mars after their god of war, Nergal; Mercury after their god of wisdom Nabu; and Jupiter after their chief god, Marduk.[71] There are too many concordances between Greek and Babylonian naming conventions for them to have arisen separately.[17] Given the differences in mythology, the correspondence was not perfect. For instance, the Babylonian Nergal was a god of war, and thus the Greeks identified him with Ares. Unlike Ares, Nergal was also a god of pestilence and ruler of the underworld.[72][73][74]

 
The Greek gods of Olympus, after whom the Solar System's Roman names of the planets are derived

Today, most people in the western world know the planets by names derived from the Olympian pantheon of gods. Although modern Greeks still use their ancient names for the planets, other European languages, because of the influence of the Roman Empire and, later, the Catholic Church, use the Roman (Latin) names rather than the Greek ones. The Romans inherited Proto-Indo-European mythology as the Greeks did and shared with them a common pantheon under different names, but the Romans lacked the rich narrative traditions that Greek poetic culture had given their gods. During the later period of the Roman Republic, Roman writers borrowed much of the Greek narratives and applied them to their own pantheon, to the point where they became virtually indistinguishable.[75] When the Romans studied Greek astronomy, they gave the planets their own gods' names: Mercurius (for Hermes), Venus (Aphrodite), Mars (Ares), Iuppiter (Zeus) and Saturnus (Cronus). Some Romans, following a belief possibly originating in Mesopotamia but developed in Hellenistic Egypt, believed that the seven gods after whom the planets were named took hourly shifts in looking after affairs on Earth. The order of shifts went Saturn, Jupiter, Mars, Sun, Venus, Mercury, Moon (from the farthest to the closest planet).[76] Therefore, the first day was started by Saturn (1st hour), second day by Sun (25th hour), followed by Moon (49th hour), Mars, Mercury, Jupiter and Venus. Because each day was named by the god that started it, this became the order of the days of the week in the Roman calendar.[77] In English, Saturday, Sunday, and Monday are straightforward translations of these Roman names. The other days were renamed after Tīw (Tuesday), Wōden (Wednesday), Þunor (Thursday), and Frīġ (Friday), the Anglo-Saxon gods considered similar or equivalent to Mars, Mercury, Jupiter, and Venus, respectively.[78]

Earth's name in English is not derived from Greco-Roman mythology. Because it was only generally accepted as a planet in the 17th century,[34] there is no tradition of naming it after a god. (The same is true, in English at least, of the Sun and the Moon, though they are no longer generally considered planets.) The name originates from the Old English word eorþe, which was the word for "ground" and "dirt" as well as the world itself.[79] As with its equivalents in the other Germanic languages, it derives ultimately from the Proto-Germanic word erþō, as can be seen in the English earth, the German Erde, the Dutch aarde, and the Scandinavian jord. Many of the Romance languages retain the old Roman word terra (or some variation of it) that was used with the meaning of "dry land" as opposed to "sea".[80] The non-Romance languages use their own native words. The Greeks retain their original name, Γή (Ge).[81]

Non-European cultures use other planetary-naming systems. India uses a system based on the Navagraha, which incorporates the seven traditional planets (Surya 'Sun', Chandra 'Moon', Budha for Mercury, Shukra ('bright') for Venus, Mangala (the god of war) for Mars, Bṛhaspati (councilor of the gods) for Jupiter, and Shani (symbolic of time) for Saturn) and the ascending and descending lunar nodes Rahu and Ketu.[82]

China and the countries of eastern Asia historically subject to Chinese cultural influence (such as Japan, Korea and Vietnam) use a naming system based on the five Chinese elements: water (Mercury 水星 "water star"), metal (Venus 金星 "metal star"), fire (Mars 火星 "fire star"), wood (Jupiter 木星 "wood star") and earth (Saturn 土星 "earth star").[77] The names of Uranus (天王星 "sky king star"), Neptune (海王星 "sea king star"), and Pluto (冥王星 "underworld king star") in Chinese, Korean, and Japanese are calques based on the roles of those gods in Roman and Greek mythology.[83][84][b] Chinese uses calques for the dwarf planets and many asteroids as well, e.g. Eris (鬩神星 "quarrel goddess star"), Ceres (穀神星 "grain goddess star"), and Pallas (智神星 "wisdom goddess star").[83]

In traditional Hebrew astronomy, the seven traditional planets have (for the most part) descriptive names – the Sun is חמה Ḥammah or "the hot one", the Moon is לבנה Levanah or "the white one", Venus is כוכב נוגה Kokhav Nogah or "the bright planet", Mercury is כוכב Kokhav or "the planet" (given its lack of distinguishing features), Mars is מאדים Ma'adim or "the red one", and Saturn is שבתאי Shabbatai or "the resting one" (in reference to its slow movement compared to the other visible planets).[86] The odd one out is Jupiter, called צדק Tzedeq or "justice".[86] Hebrew names were chosen for Uranus (אורון Oron, "small light") and Neptune (רהב Rahab, a Biblical sea monster) in 2009;[87] prior to that the names "Uranus" and "Neptune" had simply been borrowed.[88] The etymologies for the Arabic names of the planets are less well understood. Mostly agreed among scholars are Venus الزهرة (az-Zuhara, "the bright one"[89]), Earth الأرض (al-ʾArḍ, from the same root as eretz), and Saturn زُحَل (Zuḥal, "withdrawer"[90]). Multiple suggested etymologies exist for Mercury عُطَارِد (ʿUṭārid), Mars اَلْمِرِّيخ (al-Mirrīkh), and Jupiter المشتري (al-Muštarī), but there is no agreement among scholars.[91][92][93][94]

When subsequent planets were discovered in the 18th and 19th centuries, Uranus was named for a Greek deity and Neptune for a Roman one (the counterpart of Poseidon). The asteroids were initially named from mythology as well – Ceres, Juno, and Vesta are major Roman goddesses, and Pallas is an epithet of the Greek goddess Athena – but as more and more were discovered, the mythological restriction was dropped starting from Massalia in 1852.[95] Pluto was given a classical name, as it was considered a major planet when it was discovered. After more objects were discovered beyond Neptune, naming conventions depending on their orbits were put in place: those in the 2:3 resonance with Neptune (the plutinos) are given names from underworld myths, while others are given names from creation myths. Most of the trans-Neptunian dwarf planets are named after gods and goddesses from other cultures (e.g. Quaoar is named after a Tongva god), except for Orcus and Eris which continued the Roman and Greek scheme.[96][97]

The moons (including the planetary-mass ones) are generally given names with some association with their parent planet. The planetary-mass moons of Jupiter are named after four of Zeus' lovers (or other sexual partners); those of Saturn are named after Cronus' brothers and sisters, the Titans; those of Uranus are named after characters from Shakespeare and Pope (originally specifically from fairy mythology,[98] but that ended with the naming of Miranda). Neptune's planetary-mass moon Triton is named after the god's son; Pluto's planetary-mass moon Charon is named after the ferryman of the dead, who carries the souls of the newly deceased to the underworld (Pluto's domain); and Eris' only known moon Dysnomia is named after one of Eris' daughters, the spirit of lawlessness.[99]

Symbols

Main article: Planetary symbol
Most common planetary symbols
Sun
 		 Mercury
 		 Venus
 		 Earth
 		 Moon
 		 Mars
 		 Jupiter
 		 Saturn
 		 Uranus
  or  		 Neptune
 

The written symbols for Mercury, Venus, Jupiter, Saturn and possibly Mars have been traced to forms found in late Greek papyrus texts.[100] The symbols for Jupiter and Saturn are identified as monograms of the corresponding Greek names, and the symbol for Mercury is a stylized caduceus.[100]

According to Annie Scott Dill Maunder, antecedents of the planetary symbols were used in art to represent the gods associated with the classical planets. Bianchini's planisphere, discovered by Francesco Bianchini in the 18th century but produced in the 2nd century,[101] shows Greek personifications of planetary gods charged with early versions of the planetary symbols. Mercury has a caduceus; Venus has, attached to her necklace, a cord connected to another necklace; Mars, a spear; Jupiter, a staff; Saturn, a scythe; the Sun, a circlet with rays radiating from it; and the Moon, a headdress with a crescent attached.[102] The modern shapes with the cross-marks first appeared around the 16th century. According to Maunder, the addition of crosses appears to be "an attempt to give a savour of Christianity to the symbols of the old pagan gods."[102] Earth itself was not considered a classical planet; its symbol descends from a pre-heliocentric symbol for the four corners of the world.[103]

When further planets were discovered orbiting the Sun, symbols were invented for them. The most common astronomical symbol for Uranus, ⛢,[104] was invented by Johann Gottfried Köhler, and was intended to represent the newly discovered metal platinum.[105][106] An alternative symbol, ♅, was invented by Jérôme Lalande, and represents a globe with a H on top, for Uranus' discoverer Herschel.[107] Today, ⛢ is mostly used by astronomers and ♅ by astrologers, though it is possible to find each symbol in the other context.[104] The first few asteroids were similarly given abstract symbols, but as their number rose further and further, this practice stopped in favour of numbering them instead.[6] Neptune's symbol (♆) represents the god's trident.[106] The astronomical symbol for Pluto is a P-L monogram (♇),[108] though it has become less common since the IAU definition reclassified Pluto.[109] Since Pluto's reclassification, NASA has used the traditional astrological symbol of Pluto (⯓), a planetary orb over Pluto's bident.[109]

Some rarer planetary symbols in Unicode
Earth
 		 Vesta
 		 Ceres
 		 Pallas
 		 Hygiea
 		 Orcus
 		 Pluto
  or  		 Haumea
 		 Quaoar
 		 Makemake
 		 Gonggong
 		 Eris
 		 Sedna
 

The IAU discourages the use of planetary symbols in modern journal articles in favour of one-letter or (to disambiguate Mercury and Mars) two-letter abbreviations for the major planets. The symbols for the Sun and Earth are nonetheless common, as solar mass, Earth mass and similar units are common in astronomy.[110] Other planetary symbols today are mostly encountered in astrology. Astrologers have started reusing the old astronomical symbols for the first few asteroids, and continue to invent symbols for other objects, though most proposed symbols are only used by their proposers.[109] Unicode includes some relatively standard astrological symbols for some minor planets, including the dwarf planets discovered in the 21st century, though astronomical use of any of them is rare.[109][111]

Formation

Main article: Nebular hypothesis
Artists' impressions
 
A protoplanetary disk
 
Asteroids colliding during planet formation

It is not known with certainty how planets are built. The prevailing theory is that they are formed during the collapse of a nebula into a thin disk of gas and dust. A protostar forms at the core, surrounded by a rotating protoplanetary disk. Through accretion (a process of sticky collision) dust particles in the disk steadily accumulate mass to form ever-larger bodies. Local concentrations of mass known as planetesimals form, and these accelerate the accretion process by drawing in additional material by their gravitational attraction. These concentrations become ever denser until they collapse inward under gravity to form protoplanets.[112] After a planet reaches a mass somewhat larger than Mars' mass, it begins to accumulate an extended atmosphere,[113] greatly increasing the capture rate of the planetesimals by means of atmospheric drag.[114][115] Depending on the accretion history of solids and gas, a giant planet, an ice giant, or a terrestrial planet may result.[116][117][118] It is thought that the regular satellites of Jupiter, Saturn, and Uranus formed in a similar way;[119][120] however, Triton was likely captured by Neptune,[121] and Earth's Moon[122] and Pluto's Charon might have formed in collisions.[123]

When the protostar has grown such that it ignites to form a star, the surviving disk is removed from the inside outward by photoevaporation, the solar wind, Poynting–Robertson drag and other effects.[124][125] Thereafter there still may be many protoplanets orbiting the star or each other, but over time many will collide, either to form a larger, combined protoplanet or release material for other protoplanets to absorb.[126] Those objects that have become massive enough will capture most matter in their orbital neighbourhoods to become planets. Protoplanets that have avoided collisions may become natural satellites of planets through a process of gravitational capture, or remain in belts of other objects to become either dwarf planets or small bodies.[127][128]

 
 
Supernova remnant ejecta producing planet-forming material

The energetic impacts of the smaller planetesimals (as well as radioactive decay) will heat up the growing planet, causing it to at least partially melt. The interior of the planet begins to differentiate by density, with higher density materials sinking toward the core.[129] Smaller terrestrial planets lose most of their atmospheres because of this accretion, but the lost gases can be replaced by outgassing from the mantle and from the subsequent impact of comets.[130] (Smaller planets will lose any atmosphere they gain through various escape mechanisms.[131])

With the discovery and observation of planetary systems around stars other than the Sun, it is becoming possible to elaborate, revise or even replace this account. The level of metallicity—an astronomical term describing the abundance of chemical elements with an atomic number greater than 2 (helium)—appears to determine the likelihood that a star will have planets.[132][133] Hence, a metal-rich population I star is more likely to have a substantial planetary system than a metal-poor, population II star.[134]

Solar System

Main article: Solar System
 
The Solar System, including the Sun, planets, dwarf planets, and the larger moons. Distances between the bodies are not to scale.

According to the IAU definition, there are eight planets in the Solar System, which are (in increasing distance from the Sun):[1] Mercury, Venus, Earth, Mars, Jupiter, Saturn, Uranus and Neptune. Jupiter is the largest, at 318 Earth masses, whereas Mercury is the smallest, at 0.055 Earth masses.[135]

The planets of the Solar System can be divided into categories based on their composition. Terrestrials are similar to Earth, with bodies largely composed of rock and metal: Mercury, Venus, Earth, and Mars. Earth is the largest terrestrial planet.[136] Giant planets are significantly more massive than the terrestrials: Jupiter, Saturn, Uranus, and Neptune.[136] They differ from the terrestrial planets in composition. The gas giants, Jupiter and Saturn, are primarily composed of hydrogen and helium and are the most massive planets in the Solar System. Saturn is one third as massive as Jupiter, at 95 Earth masses.[137] The ice giants, Uranus and Neptune, are primarily composed of low-boiling-point materials such as water, methane, and ammonia, with thick atmospheres of hydrogen and helium. They have a significantly lower mass than the gas giants (only 14 and 17 Earth masses).[137]

Dwarf planets are gravitationally rounded, but have not cleared their orbits of other bodies. In increasing order of average distance from the Sun, the ones generally agreed among astronomers are Ceres, Orcus, Pluto, Haumea, Quaoar, Makemake, Gonggong, Eris and Sedna.[57] Ceres is the largest object in the asteroid belt, located between the orbits of Mars and Jupiter. The other eight all orbit beyond Neptune. Orcus, Pluto, Haumea, Quaoar, and Makemake orbit in the Kuiper belt, which is a second belt of small Solar System bodies beyond the orbit of Neptune. Gonggong and Eris orbit in the scattered disc, which is somewhat further out and, unlike the Kuiper belt, is unstable towards interactions with Neptune. Sedna is the largest known detached object, a population that never comes close enough to the Sun to interact with any of the classical planets; the origins of their orbits are still being debated. All nine are similar to terrestrial planets in having a solid surface, but they are made of ice and rock, rather than rock and metal. Moreover, all of them are smaller than Mercury, with Pluto being the largest known dwarf planet, and Eris being the most massive known.[138][139]

There are at least twenty planetary-mass moons or satellite planets—moons large enough to take on ellipsoidal shapes (though Dysnomia's shape has never been measured, it is massive and dense enough to be a solid body). The twenty generally agreed are as follows.[3][140]

The Moon, Io, and Europa have compositions similar to the terrestrial planets; the others are made of ice and rock like the dwarf planets, with Tethys being made of almost pure ice. (Europa is often considered an icy planet, though, because its surface ice layer makes it difficult to study its interior.[3][141]) Ganymede and Titan are larger than Mercury by radius, and Callisto almost equals it, but all three are much less massive. Mimas is the smallest object generally agreed to be a geophysical planet, at about six millionths of Earth's mass, though there are many larger bodies that may not be geophysical planets (e.g. Salacia).[57]

Planetary attributes

The tables below summarise some properties of objects generally agreed to satisfy geophysical planet definitions. There are many smaller dwarf planet candidates, such as Salacia, that have not been included in the tables because astronomers disagree on whether or not they are dwarf planets. The diameters, masses, orbital periods, and rotation periods of the major planets are available from the Jet Propulsion Laboratory.[135] JPL also provides their semi-major axes, inclinations, and eccentricities of planetary orbits,[142] and the axial tilts are taken from their Horizons database.[143] Other information is summarized by NASA.[144] The data for the dwarf planets and planetary-mass moons is taken from list of gravitationally rounded objects of the Solar System, with sources listed there.

Name Equatorial
diameter		 Mass Semi-major axis (AU) Orbital period
(years) 		Inclination
to the ecliptic (°) 		Orbital
eccentricity 		Rotation period
(days) 		Confirmed
moons 		Axial tilt (°) Rings Atmosphere
Major planets
  Mercury 0.383 0.06 0.39 0.24 7.00 0.206 58.65 0 0.04 no minimal
  Venus 0.949 0.81 0.72 0.62 3.39 0.007 243.02 0 177.30 no CO2, N2
  Earth 1.000 1.00 1.00 1.00 0.0 0.017 1.00 1 23.44 no N2, O2, Ar
  Mars 0.532 0.11 1.52 1.88 1.85 0.093 1.03 2 25.19 no CO2, N2, Ar
  Jupiter 11.209 317.83 5.20 11.86 1.30 0.048 0.41 84 3.13 yes H2, He
  Saturn 9.449 95.16 9.54 29.45 2.49 0.054 0.44 83 26.73 yes H2, He
  Uranus 4.007 14.54 19.19 84.02 0.773 0.047 0.72 27 97.77 yes H2, He, CH4
  Neptune 3.883 17.15 30.07 164.79 1.77 0.009 0.67 14 28.32 yes H2, He, CH4
Dwarf planets
  Ceres 0.0742 0.00016 2.77 4.60 10.59 0.080 0.38 0 4 no minimal
  Orcus 0.072 0.0001 39.42 247.5 20.59 0.226 ? 1 ? ? ?
  Pluto 0.186 0.0022 39.48 247.9 17.14 0.249 6.39 5 119.6 no N2, CH4, CO
  Haumea 0.13 0.0007 43.34 283.8 28.21 0.195 0.16 2 126 yes ?
  Quaoar 0.087 0.0003 43.69 288.0 7.99 0.038 0.37 1 ? ? ?
  Makemake 0.11 0.0005 45.79 306.2 28.98 0.161 0.95 1 ? ? minimal
  Gonggong 0.10 0.0003 67.33 552.5 30.74 0.506 0.93 1 ? ? ?
  Eris 0.18 0.0028 67.67 559 44.04 0.436 15.79 1 78 ? ?
  Sedna 0.078 ? 525.86 12059 11.93 0.855 0.43 0 ? ? ?
Color legend:   terrestrial planets   gas giants   ice giants (both are giant planets  dwarf planets

Measured relative to Earth.
The Earth's mass is approximately 5.972 × 1024 kilograms, and its equatorial radius is approximately 6,378 kilometres.[135]

As all the planetary-mass moons exhibit synchronous rotation, their rotation periods equal their orbital periods.

Planetary-mass moons
Name Equatorial
diameter		 Mass Semi-major axis (km) Orbital period
(days) 		Inclination
to primary's equator (°) 		Orbital
eccentricity 		Axial tilt (°) Atmosphere
  Moon 0.272 0.0123 384,399 27.322 18.29–28.58 0.0549 6.68 minimal
 1 Io 0.285 0.0150 421,600 1.769 0.04 0.0041 ≈0 minimal
 2 Europa 0.246 0.00804 670,900 3.551 0.47 0.009 ≈0.1 minimal
 3 Ganymede 0.413 0.0248 1,070,400 7.155 1.85 0.0013 ≈0.2 minimal
 4 Callisto 0.378 0.0180 1,882,700 16.689 0.2 0.0074 ≈0–2 minimal
 1 Mimas 0.031 0.00000628 185,520 0.942 1.51 0.0202 ≈0
 2 Enceladus 0.04 0.0000181 237,948 1.370 0.02 0.0047 ≈0 minimal
 3 Tethys 0.084 0.000103 294,619 1.888 1.51 0.02 ≈0
 4 Dione 0.088 0.000183 377,396 2.737 0.019 0.002 ≈0 minimal
 5 Rhea 0.12 0.000386 527,108 4.518 0.345 0.001 ≈0 minimal
 6 Titan 0.404 0.0225 1,221,870 15.945 0.33 0.0288 ≈0.3 N2, CH4
 8 Iapetus 0.115 0.000302 3,560,820 79.322 14.72 0.0286 ≈0
 5 Miranda 0.037 0.0000110 129,390 1.414 4.22 0.0013 ≈0
 1 Ariel 0.091 0.000226 190,900 2.520 0.31 0.0012 ≈0
 2 Umbriel 0.092 0.00020 266,000 4.144 0.36 0.005 ≈0
 3 Titania 0.124 0.00059 436,300 8.706 0.14 0.0011 ≈0
 4 Oberon 0.119 0.000505 583,519 13.46 0.10 0.0014 ≈0
 1 Triton 0.212 0.00358 354,759 5.877 157 0.00002 ≈0.7 N2, CH4
 1 Charon 0.095 0.000255 17,536 6.387 0.001 0.0022 ≈0
 1 Dysnomia 0.057 0.00005–0.00008 37,300 15.786 ≈0 0.0062 ≈0
Color legend:   predominantly rocky   predominantly icy

Measured relative to Earth.

Exoplanets

Main article: Exoplanet
 
Exoplanet detections per year as of June 2022 (by NASA Exoplanet Archive)[145]

An exoplanet (extrasolar planet) is a planet outside the Solar System. As of 1 January 2023, there are 5,297 confirmed exoplanets in 3,904 planetary systems, with 850 systems having more than one planet.[146] Known exoplanets range in size from gas giants about twice as large as Jupiter down to just over the size of the Moon. Analysis of gravitational microlensing data suggests a minimum average of 1.6 bound planets for every star in the Milky Way.[147]

In early 1992, radio astronomers Aleksander Wolszczan and Dale Frail announced the discovery of two planets orbiting the pulsar PSR 1257+12.[46] This discovery was confirmed, and is generally considered to be the first definitive detection of exoplanets. Researchers suspect they formed from a disk remnant left over from the supernova that produced the pulsar.[148]

The first confirmed discovery of an extrasolar planet orbiting an ordinary main-sequence star occurred on 6 October 1995, when Michel Mayor and Didier Queloz of the University of Geneva announced the detection of 51 Pegasi b, an exoplanet around 51 Pegasi.[149] From then until the Kepler mission most known extrasolar planets were gas giants comparable in mass to Jupiter or larger as they were more easily detected. The catalog of Kepler candidate planets consists mostly of planets the size of Neptune and smaller, down to smaller than Mercury.[150][151]

In 2011, the Kepler Space Telescope team reported the discovery of the first Earth-sized extrasolar planets orbiting a Sun-like star, Kepler-20e and Kepler-20f.[152][153][154] Since that time, more than 100 planets have been identified that are approximately the same size as Earth, 20 of which orbit in the habitable zone of their star – the range of orbits where a terrestrial planet could sustain liquid water on its surface, given enough atmospheric pressure.[155][156][157] One in five Sun-like stars is thought to have an Earth-sized planet in its habitable zone, which suggests that the nearest would be expected to be within 12 light-years distance from Earth.[c] The frequency of occurrence of such terrestrial planets is one of the variables in the Drake equation, which estimates the number of intelligent, communicating civilizations that exist in the Milky Way.[160]

There are types of planets that do not exist in the Solar System: super-Earths and mini-Neptunes, which have masses between that of Earth and Neptune. Such planets could be rocky like Earth or a mixture of volatiles and gas like Neptune—the dividing line between the two possibilities is currently thought to occur at about twice the mass of Earth.[161] The planet Gliese 581c, with mass 5.5–10.4 times the mass of Earth,[162] attracted attention upon its discovery for potentially being in the habitable zone,[163] though later studies concluded that it is actually too close to its star to be habitable.[164] Exoplanets have been found that are much closer to their parent star than any planet in the Solar System is to the Sun. Mercury, the closest planet to the Sun at 0.4 AU, takes 88 days for an orbit, but ultra-short period planets can orbit in less than a day. The Kepler-11 system has five of its planets in shorter orbits than Mercury's, all of them much more massive than Mercury. There are hot Jupiters, such as 51 Pegasi b,[149] that orbit very close to their star and may evaporate to become chthonian planets, which are the leftover cores. There are also exoplanets that are much farther from their star. Neptune is 30 AU from the Sun and takes 165 years to orbit, but there are exoplanets that are thousands of AU from their star and take more than a million years to orbit. e.g. COCONUTS-2b.[165]

Attributes

Although each planet has unique physical characteristics, a number of broad commonalities do exist among them. Some of these characteristics, such as rings or natural satellites, have only as yet been observed in planets in the Solar System, whereas others are commonly observed in extrasolar planets.[166]

Dynamic characteristics

Orbit

Main articles: Orbit and orbital elements
See also: Kepler's laws of planetary motion and Exoplanetology § Orbital parameters
 
The orbit of the planet Neptune compared to that of Pluto. Note the elongation of Pluto's orbit in relation to Neptune's (eccentricity), as well as its large angle to the ecliptic (inclination).

In the Solar System, all the planets orbit the Sun in the same direction as the Sun rotates: counter-clockwise as seen from above the Sun's north pole. At least one extrasolar planet, WASP-17b, has been found to orbit in the opposite direction to its star's rotation.[167] The period of one revolution of a planet's orbit is known as its sidereal period or year.[168] A planet's year depends on its distance from its star; the farther a planet is from its star, the longer the distance it must travel and the slower its speed, since it is less affected by its star's gravity.

No planet's orbit is perfectly circular, and hence the distance of each from the host star varies over the course of its year. The closest approach to its star is called its periastron, or perihelion in the Solar System, whereas its farthest separation from the star is called its apastron (aphelion). As a planet approaches periastron, its speed increases as it trades gravitational potential energy for kinetic energy, just as a falling object on Earth accelerates as it falls. As the planet nears apastron, its speed decreases, just as an object thrown upwards on Earth slows down as it reaches the apex of its trajectory.[169]

Each planet's orbit is delineated by a set of elements:

  • The eccentricity of an orbit describes the elongation of a planet's elliptical (oval) orbit. Planets with low eccentricities have more circular orbits, whereas planets with high eccentricities have more elliptical orbits. The planets and large moons in the Solar System have relatively low eccentricities, and thus nearly circular orbits.[168] The comets and many Kuiper belt objects, as well as several extrasolar planets, have very high eccentricities, and thus exceedingly elliptical orbits.[170][171]
  • The semi-major axis gives the size of the orbit. It is the distance from the midpoint to the longest diameter of its elliptical orbit. This distance is not the same as its apastron, because no planet's orbit has its star at its exact centre.[168]
  • The inclination of a planet tells how far above or below an established reference plane its orbit is tilted. In the Solar System, the reference plane is the plane of Earth's orbit, called the ecliptic. For extrasolar planets, the plane, known as the sky plane or plane of the sky, is the plane perpendicular to the observer's line of sight from Earth.[172] The eight planets of the Solar System all lie very close to the ecliptic; comets and Kuiper belt objects like Pluto are at far more extreme angles to it.[173] The large moons are generally not very inclined to their parent planets' equators, but Earth's Moon, Saturn's Iapetus, and Neptune's Triton are exceptions. Triton is unique among the large moons in that it orbits retrograde, i.e. in the direction opposite to its parent planet's rotation.[174]
  • The points at which a planet crosses above and below its reference plane are called its ascending and descending nodes.[168] The longitude of the ascending node is the angle between the reference plane's 0 longitude and the planet's ascending node. The argument of periapsis (or perihelion in the Solar System) is the angle between a planet's ascending node and its closest approach to its star.[168]

Axial tilt

Main article: Axial tilt
 
Earth's axial tilt is about 23.4°. It oscillates between 22.1° and 24.5° on a 41,000-year cycle and is currently decreasing.

Planets have varying degrees of axial tilt; they spin at an angle to the plane of their stars' equators. This causes the amount of light received by each hemisphere to vary over the course of its year; when the northern hemisphere points away from its star, the southern hemisphere points towards it, and vice versa. Each planet therefore has seasons, resulting in changes to the climate over the course of its year. The time at which each hemisphere points farthest or nearest from its star is known as its solstice. Each planet has two in the course of its orbit; when one hemisphere has its summer solstice with its day being the longest, the other has its winter solstice when its day is shortest. The varying amount of light and heat received by each hemisphere creates annual changes in weather patterns for each half of the planet. Jupiter's axial tilt is very small, so its seasonal variation is minimal; Uranus, on the other hand, has an axial tilt so extreme it is virtually on its side, which means that its hemispheres are either continually in sunlight or continually in darkness around the time of its solstices.[175] Among extrasolar planets, axial tilts are not known for certain, though most hot Jupiters are believed to have a negligible axial tilt as a result of their proximity to their stars.[176]

Rotation

See also: Exoplanetology § Rotation and axial tilt

The planets rotate around invisible axes through their centres. A planet's rotation period is known as a stellar day. Most of the planets in the Solar System rotate in the same direction as they orbit the Sun, which is counter-clockwise as seen from above the Sun's north pole. The exceptions are Venus[177] and Uranus,[178] which rotate clockwise, though Uranus's extreme axial tilt means there are differing conventions on which of its poles is "north", and therefore whether it is rotating clockwise or anti-clockwise.[179] Regardless of which convention is used, Uranus has a retrograde rotation relative to its orbit.[178]

 
Comparison of the rotation period (sped up 10 000 times, negative values denoting retrograde), flattening and axial tilt of the planets and the Moon (SVG animation)

The rotation of a planet can be induced by several factors during formation. A net angular momentum can be induced by the individual angular momentum contributions of accreted objects. The accretion of gas by the giant planets contributes to the angular momentum. Finally, during the last stages of planet building, a stochastic process of protoplanetary accretion can randomly alter the spin axis of the planet.[180] There is great variation in the length of day between the planets, with Venus taking 243 days to rotate, and the giant planets only a few hours.[144] The rotational periods of extrasolar planets are not known, but for hot Jupiters, their proximity to their stars means that they are tidally locked (that is, their orbits are in sync with their rotations). This means, they always show one face to their stars, with one side in perpetual day, the other in perpetual night.[181] Mercury and Venus, the closest planets to the Sun, similarly exhibit very slow rotation: Mercury is tidally locked into a 3:2 spin–orbit resonance (rotating three times for every two revolutions around the Sun),[182] and Venus' rotation may be in equilibrium between tidal forces slowing it down and atmospheric tides created by solar heating speeding it up.[183][184]

All the large moons are tidally locked to their parent planets;[185] Pluto and Charon are tidally locked to each other,[186] as are Eris and Dysnomia.[140] The other dwarf planets with known rotation periods rotate faster than Earth; Haumea rotates so fast that it has been distorted into a triaxial ellipsoid.[187] The exoplanet Tau Boötis b and its parent star Tau Boötis appear to be mutually tidally locked.[188][189]

Orbital clearing

Main article: Clearing the neighbourhood

The defining dynamic characteristic of a planet, according to the IAU definition, is that it has cleared its neighborhood. A planet that has cleared its neighborhood has accumulated enough mass to gather up or sweep away all the planetesimals in its orbit. In effect, it orbits its star in isolation, as opposed to sharing its orbit with a multitude of similar-sized objects. As described above, this characteristic was mandated as part of the IAU's official definition of a planet in August 2006.[1] Although to date this criterion only applies to the Solar System, a number of young extrasolar systems have been found in which evidence suggests orbital clearing is taking place within their circumstellar discs.[190]

Physical characteristics

Size and shape

See also: Earth § Size and shape, Astronomical body § Size, and Planetary coordinate system

Gravity causes planets to be pulled into a roughly spherical shape, so a planet's size can be expressed roughly by an average radius (for example, Earth radius or Jupiter radius). However, planets are not perfectly spherical; for example, the Earth's rotation causes it to be slightly flattened at the poles with a bulge around the equator.[191] Therefore, a better approximation of Earth's shape is an oblate spheroid, whose equatorial diameter is 43 kilometers (27 mi) larger than the pole-to-pole diameter.[192] Generally, a planet's shape may be described by giving polar and equatorial radii of a spheroid or specifying a reference ellipsoid. From such a specification, the planet's flattening, surface area, and volume can be calculated; its normal gravity can be computed knowing its size, shape, rotation rate and mass.[193]

Mass

Main article: Planetary mass

A planet's defining physical characteristic is that it is massive enough for the force of its own gravity to dominate over the electromagnetic forces binding its physical structure, leading to a state of hydrostatic equilibrium. This effectively means that all planets are spherical or spheroidal. Up to a certain mass, an object can be irregular in shape, but beyond that point, which varies depending on the chemical makeup of the object, gravity begins to pull an object towards its own centre of mass until the object collapses into a sphere.[194]

Mass is the prime attribute by which planets are distinguished from stars. While the lower stellar mass limit is estimated to be around 75 times that of Jupiter (MJ), the upper planetary mass limit for planethood is only roughly 13 MJ for objects with solar-type isotopic abundance, beyond which it achieves conditions suitable for nuclear fusion of deuterium. Other than the Sun, no objects of such mass exist in the Solar System; but there are exoplanets of this size. The 13 MJ limit is not universally agreed upon and the Extrasolar Planets Encyclopaedia includes objects up to 60 MJ,[195] and the Exoplanet Data Explorer up to 24 MJ.[196]

The smallest known exoplanet with an accurately known mass is PSR B1257+12A, one of the first extrasolar planets discovered, which was found in 1992 in orbit around a pulsar. Its mass is roughly half that of the planet Mercury.[197] Even smaller is WD 1145+017 b, orbiting a white dwarf; its mass is roughly that of the dwarf planet Haumea, and it is typically termed a minor planet.[198] The smallest known planet orbiting a main-sequence star other than the Sun is Kepler-37b, with a mass (and radius) that is probably slightly higher than that of the Moon.[151]

Internal differentiation

Main article: Planetary differentiation
 
Illustration of the interior of Jupiter, with a rocky core overlaid by a deep layer of metallic hydrogen

Every planet began its existence in an entirely fluid state; in early formation, the denser, heavier materials sank to the centre, leaving the lighter materials near the surface. Each therefore has a differentiated interior consisting of a dense planetary core surrounded by a mantle that either is or was a fluid. The terrestrial planets' mantles are sealed within hard crusts,[199] but in the giant planets the mantle simply blends into the upper cloud layers. The terrestrial planets have cores of elements such as iron and nickel, and mantles of silicates. Jupiter and Saturn are believed to have cores of rock and metal surrounded by mantles of metallic hydrogen.[200] Uranus and Neptune, which are smaller, have rocky cores surrounded by mantles of water, ammonia, methane and other ices.[201] The fluid action within these planets' cores creates a geodynamo that generates a magnetic field.[199] Similar differentiation processes are believed to have occurred on some of the large moons and dwarf planets,[57] though the process may not always have been completed: Ceres, Callisto, and Titan appear to be incompletely differentiated.[202][203]

Atmosphere

Main articles: Atmosphere and extraterrestrial atmospheres
See also: Extraterrestrial skies
 
Earth's atmosphere

All of the Solar System planets except Mercury[204] have substantial atmospheres because their gravity is strong enough to keep gases close to the surface. Saturn's largest moon Titan also has a substantial atmosphere thicker than that of Earth;[205] Neptune's largest moon Triton[206] and the dwarf planet Pluto have more tenuous atmospheres.[207] The larger giant planets are massive enough to keep large amounts of the light gases hydrogen and helium, whereas the smaller planets lose these gases into space.[208] The composition of Earth's atmosphere is different from the other planets because the various life processes that have transpired on the planet have introduced free molecular oxygen.[209]

Planetary atmospheres are affected by the varying insolation or internal energy, leading to the formation of dynamic weather systems such as hurricanes (on Earth), planet-wide dust storms (on Mars), a greater-than-Earth-sized anticyclone on Jupiter (called the Great Red Spot), and holes in the atmosphere (on Neptune).[175] Weather patterns detected on exoplanets include a hot region on HD 189733 b twice the size of the Great Red Spot,[210] as well as clouds on the hot Jupiter Kepler-7b,[211] the super-Earth Gliese 1214 b and others.[212][213]

Hot Jupiters, due to their extreme proximities to their host stars, have been shown to be losing their atmospheres into space due to stellar radiation, much like the tails of comets.[214][215] These planets may have vast differences in temperature between their day and night sides that produce supersonic winds,[216] although multiple factors are involved and the details of the atmospheric dynamics that affect the day-night temperature difference are complex.[217][218]

Magnetosphere

Main article: Magnetosphere

One important characteristic of the planets is their intrinsic magnetic moments, which in turn give rise to magnetospheres. The presence of a magnetic field indicates that the planet is still geologically alive. In other words, magnetized planets have flows of electrically conducting material in their interiors, which generate their magnetic fields. These fields significantly change the interaction of the planet and solar wind. A magnetized planet creates a cavity in the solar wind around itself called the magnetosphere, which the wind cannot penetrate. The magnetosphere can be much larger than the planet itself. In contrast, non-magnetized planets have only small magnetospheres induced by interaction of the ionosphere with the solar wind, which cannot effectively protect the planet.[219]

Of the eight planets in the Solar System, only Venus and Mars lack such a magnetic field.[219] Of the magnetized planets the magnetic field of Mercury is the weakest, and is barely able to deflect the solar wind. Jupiter's moon Ganymede has a magnetic field several times stronger, and Jupiter's is the strongest in the Solar System (so intense in fact that it poses a serious health risk to future crewed missions to all its moons inward of Callisto[220]). The magnetic fields of the other giant planets, measured at their surfaces, are roughly similar in strength to that of Earth, but their magnetic moments are significantly larger. The magnetic fields of Uranus and Neptune are strongly tilted relative to the planets' rotational axes and displaced from the planets' centres.[219]

In 2003, a team of astronomers in Hawaii observing the star HD 179949 detected a bright spot on its surface, apparently created by the magnetosphere of an orbiting hot Jupiter.[221][222]

Secondary characteristics

Main articles: Natural satellite and planetary ring

Several planets or dwarf planets in the Solar System (such as Neptune and Pluto) have orbital periods that are in resonance with each other or with smaller bodies. This is common in satellite systems (e.g. the resonance between Io, Europa, and Ganymede around Jupiter, or between Enceladus and Dione around Saturn). All except Mercury and Venus have natural satellites, often called "moons". Earth has one, Mars has two, and the giant planets have numerous moons in complex planetary-type systems. Except for Ceres and Sedna, all the consensus dwarf planets are known to have at least one moon as well. Many moons of the giant planets have features similar to those on the terrestrial planets and dwarf planets, and some have been studied as possible abodes of life (especially Europa and Enceladus).[223][224][225][226][227]

The four giant planets are orbited by planetary rings of varying size and complexity. The rings are composed primarily of dust or particulate matter, but can host tiny 'moonlets' whose gravity shapes and maintains their structure. Although the origins of planetary rings is not precisely known, they are believed to be the result of natural satellites that fell below their parent planet's Roche limit and were torn apart by tidal forces.[228][229] The dwarf planet Haumea also has a ring.[230]

No secondary characteristics have been observed around extrasolar planets. The sub-brown dwarf Cha 110913-773444, which has been described as a rogue planet, is believed to be orbited by a tiny protoplanetary disc[231] and the sub-brown dwarf OTS 44 was shown to be surrounded by a substantial protoplanetary disk of at least 10 Earth masses.[232]

See also

Notes

  1. ^ Margot's parameter[66] is not to be confused with the famous mathematical constant π≈3.14159265 ... .
  2. ^ In Vietnamese, calques are more common than directly reading these names as Sino-Vietnamese, e.g. sao Thuỷ rather than Thuỷ tinh for Mercury. Pluto is not sao Minh Vương but sao Diêm Vương "Yama star".[85]
  3. ^ Here, "Earth-sized" means 1–2 Earth radii, and "habitable zone" means the region with 0.25 to 4 times Earth's stellar flux (corresponding to 0.5–2 AU for the Sun). Data for G-type stars like the Sun is not available. This statistic is an extrapolation from data on K-type stars.[158][159]

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January 20, 2023
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This article is about the astronomical object For other uses see Planet disambiguation The eight known planets of the Solar System according to the IAU definition The terrestrial planetsMercury Venus Earth and MarsThe giant planetsJupiter and Saturn gas giants Uranus and Neptune ice giants Shown in order from the Sun and in true color Sizes are not to scale A planet is a large rounded astronomical body that is neither a star nor its remnant The best available theory of planet formation is the nebular hypothesis which posits that an interstellar cloud collapses out of a nebula to create a young protostar orbited by a protoplanetary disk Planets grow in this disk by the gradual accumulation of material driven by gravity a process called accretion The Solar System has at least eight planets the terrestrial planets Mercury Venus Earth and Mars and the giant planets Jupiter Saturn Uranus and Neptune These planets each rotate around an axis tilted with respect to its orbital pole All of them possess an atmosphere although that of Mercury is tenuous and some share such features as ice caps seasons volcanism hurricanes tectonics and even hydrology Apart from Venus and Mars the Solar System planets generate magnetic fields and all except Venus and Mercury have natural satellites The giant planets bear planetary rings the most prominent being those of Saturn The word planet probably comes from the Greek planḗtai meaning wanderers In antiquity this word referred to the Sun Moon and five points of light visible by the naked eye that moved across the background of the stars namely Mercury Venus Mars Jupiter and Saturn Planets have historically had religious associations multiple cultures identified celestial bodies with gods and these connections with mythology and folklore persist in the schemes for naming newly discovered Solar System bodies Earth itself was recognized as a planet when heliocentrism supplanted geocentrism during the 16th and 17th centuries With the development of the telescope the meaning of planet broadened to include objects only visible with assistance the ice giants Uranus and Neptune Ceres and other bodies later recognized to be part of the asteroid belt and Pluto later found to be the largest member of the collection of icy bodies known as the Kuiper belt The discovery of other large objects in the Kuiper belt particularly Eris spurred debate about how exactly to define a planet The International Astronomical Union IAU adopted a standard by which the four terrestrials and four giants qualify placing Ceres Pluto and Eris in the category of dwarf planet 1 2 3 although many planetary scientists have continued to apply the term planet more broadly 4 Further advances in astronomy led to the discovery of over five thousand planets outside the Solar System termed exoplanets These include hot Jupiters giant planets that orbit close to their parent stars like 51 Pegasi b super Earths like Gliese 581c that have masses in between that of Earth and Neptune and planets smaller than Earth like Kepler 20e Multiple exoplanets have been found to orbit in the habitable zones of their stars but Earth remains the only planet known to support life Contents 1 History 1 1 Babylon 1 2 Greco Roman astronomy 1 3 Medieval astronomy 1 4 Scientific Revolution and new planets 1 5 20th century 1 6 21st century 2 Definition and similar concepts 2 1 Exoplanet 2 2 Planetary mass object 3 Mythology and naming 3 1 Symbols 4 Formation 5 Solar System 5 1 Planetary attributes 6 Exoplanets 7 Attributes 7 1 Dynamic characteristics 7 1 1 Orbit 7 1 2 Axial tilt 7 1 3 Rotation 7 1 4 Orbital clearing 7 2 Physical characteristics 7 2 1 Size and shape 7 2 2 Mass 7 2 3 Internal differentiation 7 2 4 Atmosphere 7 2 5 Magnetosphere 7 3 Secondary characteristics 8 See also 9 Notes 10 References 11 External linksHistoryFurther information History of astronomy and Timeline of Solar System astronomy 1660 illustration of Claudius Ptolemy s geocentric model The idea of planets has evolved over its history from the divine lights of antiquity to the earthly objects of the scientific age The concept has expanded to include worlds not only in the Solar System but in multitudes of other extrasolar systems The consensus definition as to what counts as a planet vs other objects orbiting the Sun has changed several times previously encompassing asteroids moons and dwarf planets like Pluto 5 6 7 and there continues to be some disagreement today 7 The five classical planets of the Solar System being visible to the naked eye have been known since ancient times and have had a significant impact on mythology religious cosmology and ancient astronomy In ancient times astronomers noted how certain lights moved across the sky as opposed to the fixed stars which maintained a constant relative position in the sky 8 Ancient Greeks called these lights planhtes ἀsteres planetes asteres wandering stars or simply planῆtai planetai wanderers 9 from which today s word planet was derived 10 11 12 In ancient Greece China Babylon and indeed all pre modern civilizations 13 14 it was almost universally believed that Earth was the center of the Universe and that all the planets circled Earth The reasons for this perception were that stars and planets appeared to revolve around Earth each day 15 and the apparently common sense perceptions that Earth was solid and stable and that it was not moving but at rest 16 Babylon Main article Babylonian astronomy The first civilization known to have a functional theory of the planets were the Babylonians who lived in Mesopotamia in the first and second millennia BC The oldest surviving planetary astronomical text is the Babylonian Venus tablet of Ammisaduqa a 7th century BC copy of a list of observations of the motions of the planet Venus that probably dates as early as the second millennium BC 17 The MUL APIN is a pair of cuneiform tablets dating from the 7th century BC that lays out the motions of the Sun Moon and planets over the course of the year 18 Late Babylonian astronomy is the origin of Western astronomy and indeed all Western efforts in the exact sciences 19 The Enuma anu enlil written during the Neo Assyrian period in the 7th century BC 20 comprises a list of omens and their relationships with various celestial phenomena including the motions of the planets 21 22 Venus Mercury and the outer planets Mars Jupiter and Saturn were all identified by Babylonian astronomers These would remain the only known planets until the invention of the telescope in early modern times 23 Greco Roman astronomy See also Greek astronomy The ancient Greeks initially did not attach as much significance to the planets as the Babylonians The Pythagoreans in the 6th and 5th centuries BC appear to have developed their own independent planetary theory which consisted of the Earth Sun Moon and planets revolving around a Central Fire at the center of the Universe Pythagoras or Parmenides is said to have been the first to identify the evening star Hesperos and morning star Phosphoros as one and the same Aphrodite Greek corresponding to Latin Venus 24 though this had long been known in Mesopotamia 25 26 In the 3rd century BC Aristarchus of Samos proposed a heliocentric system according to which Earth and the planets revolved around the Sun The geocentric system remained dominant until the Scientific Revolution 16 By the 1st century BC during the Hellenistic period the Greeks had begun to develop their own mathematical schemes for predicting the positions of the planets These schemes which were based on geometry rather than the arithmetic of the Babylonians would eventually eclipse the Babylonians theories in complexity and comprehensiveness and account for most of the astronomical movements observed from Earth with the naked eye These theories would reach their fullest expression in the Almagest written by Ptolemy in the 2nd century CE So complete was the domination of Ptolemy s model that it superseded all previous works on astronomy and remained the definitive astronomical text in the Western world for 13 centuries 17 27 To the Greeks and Romans there were seven known planets each presumed to be circling Earth according to the complex laws laid out by Ptolemy They were in increasing order from Earth in Ptolemy s order and using modern names the Moon Mercury Venus the Sun Mars Jupiter and Saturn 12 27 28 Medieval astronomy Main articles Astronomy in the medieval Islamic world and Indian astronomy After the fall of the Western Roman Empire astronomy developed further in India and the medieval Islamic world In 499 CE the Indian astronomer Aryabhata propounded a planetary model that explicitly incorporated Earth s rotation about its axis which he explains as the cause of what appears to be an apparent westward motion of the stars He also theorised that the orbits of planets were elliptical 29 Aryabhata s followers were particularly strong in South India where his principles of the diurnal rotation of Earth among others were followed and a number of secondary works were based on them 30 The astronomy of the Islamic Golden Age mostly took place in the Middle East Central Asia Al Andalus and North Africa and later in the Far East and India These astronomers like the polymath Ibn al Haytham generally accepted geocentrism although they did dispute Ptolemy s system of epicycles and sought alternatives The 10th century astronomer Abu Sa id al Sijzi accepted that the Earth rotates around its axis 31 In the 11th century the transit of Venus was observed by Avicenna 32 His contemporary Al Biruni devised a method of determining the Earth s radius using trigonometry that unlike the older method of Eratosthenes only required observations at a single mountain 33 Scientific Revolution and new planets See also Heliocentrism With the advent of the Scientific Revolution and the heliocentric model of Copernicus Galileo and Kepler use of the term planet changed from something that moved around the sky relative to the fixed star to a body that orbited the Sun directly a primary planet or indirectly a secondary or satellite planet Thus the Earth was added to the roster of planets 34 and the Sun was removed The Copernican count of primary planets stood until 1781 when William Herschel discovered Uranus 35 When four satellites of Jupiter the Galilean moons and five of Saturn were discovered in the 17th century they were thought of as satellite planets or secondary planets orbiting the primary planets though in the following decades they would come to be called simply satellites for short Scientists generally considered planetary satellites to also be planets until about the 1920s although this usage was not common among non scientists 7 In the first decade of the 19th century four new planets were discovered Ceres in 1801 Pallas in 1802 Juno in 1804 and Vesta in 1807 It soon became apparent that they were rather different from previously known planets they shared the same general region of space between Mars and Jupiter the asteroid belt with sometimes overlapping orbits This was an area where only one planet had been expected and they were much much smaller than all other planets indeed it was suspected that they might be shards of a larger planet that had broken up Herschel called them asteroids from the Greek for starlike because even in the largest telescopes they resembled stars without a resolvable disk 6 36 The situation was stable for four decades but in the mid 1840s several additional asteroids were discovered Astraea in 1845 Hebe in 1847 Iris in 1847 Flora in 1848 Metis in 1848 and Hygiea in 1849 and soon new planets were discovered every year As a result astronomers began tabulating the asteroids minor planets separately from the major planets and assigning them numbers instead of abstract planetary symbols 6 although they continued to be considered as small planets 37 Neptune was discovered in 1846 its position having been predicted thanks to its gravitational influence upon Uranus Because the orbit of Mercury appeared to be affected in a similar way it was believed in the late 19th century that there might be another planet even closer to the Sun However the discrepancy between Mercury s orbit and the predictions of Newtonian gravity was instead explained by an improved theory of gravity Einstein s general relativity 38 39 20th century Pluto was discovered in 1930 After initial observations led to the belief that it was larger than Earth 40 the object was immediately accepted as the ninth major planet Further monitoring found the body was actually much smaller in 1936 Ray Lyttleton suggested that Pluto may be an escaped satellite of Neptune 41 and Fred Whipple suggested in 1964 that Pluto may be a comet 42 The discovery of its large moon Charon in 1978 showed that Pluto was only 0 2 the mass of Earth 43 As this was still substantially more massive than any known asteroid and because no other trans Neptunian objects had been discovered at that time Pluto kept its planetary status only officially losing it in 2006 44 45 In the 1950s Gerard Kuiper published papers on the origin of the asteroids He recognised that asteroids were typically not spherical as had previously been thought and that the asteroid families were remnants of collisions Thus he differentiated between the largest asteroids as true planets versus the smaller ones as collisional fragments From the 1960s onwards the term minor planet was mostly displaced by the term asteroid and references to the asteroids as planets in the literature became scarce except for the geologically evolved largest three Ceres and less often Pallas and Vesta 37 The beginning of Solar System exploration by space probes in the 1960s spurred a renewed interest in planetary science A split in definitions regarding satellites occurred around then planetary scientists began to reconsider the large moons as also being planets but astronomers who were not planetary scientists generally did not 7 In 1992 astronomers Aleksander Wolszczan and Dale Frail announced the discovery of planets around a pulsar PSR B1257 12 46 This discovery is generally considered to be the first definitive detection of a planetary system around another star Then on 6 October 1995 Michel Mayor and Didier Queloz of the Geneva Observatory announced the first definitive detection of an exoplanet orbiting an ordinary main sequence star 51 Pegasi 47 The discovery of extrasolar planets led to another ambiguity in defining a planet the point at which a planet becomes a star Many known extrasolar planets are many times the mass of Jupiter approaching that of stellar objects known as brown dwarfs Brown dwarfs are generally considered stars due to their theoretical ability to fuse deuterium a heavier isotope of hydrogen Although objects more massive than 75 times that of Jupiter fuse simple hydrogen objects of 13 Jupiter masses can fuse deuterium Deuterium is quite rare constituting less than 0 0026 of the hydrogen in the galaxy and most brown dwarfs would have ceased fusing deuterium long before their discovery making them effectively indistinguishable from supermassive planets 48 21st century With the discovery during the latter half of the 20th century of more objects within the Solar System and large objects around other stars disputes arose over what should constitute a planet There were particular disagreements over whether an object should be considered a planet if it was part of a distinct population such as a belt or if it was large enough to generate energy by the thermonuclear fusion of deuterium 49 Complicating the matter even further bodies too small to generate energy by fusing deuterium can form by gas cloud collapse just like stars and brown dwarfs even down to the mass of Jupiter 50 there was thus disagreement about whether how a body formed should be taken into account 49 A growing number of astronomers argued for Pluto to be declassified as a planet because many similar objects approaching its size had been found in the same region of the Solar System the Kuiper belt during the 1990s and early 2000s Pluto was found to be just one small body in a population of thousands 49 They often referred to the demotion of the asteroids as a precedent although that had been done based on their geophysical differences from planets rather than their being in a belt 7 Some of the larger trans Neptunian objects such as Quaoar Sedna Eris and Haumea 51 were heralded in the popular press as the tenth planet The announcement of Eris in 2005 an object 27 more massive than Pluto created the impetus for an official definition of a planet 49 as considering Pluto a planet would logically have demanded that Eris be considered a planet as well Since different procedures were in place for naming planets versus non planets this created an urgent situation because under the rules Eris could not be named without defining what a planet was 7 At the time it was also thought that the size required for a trans Neptunian object to become round was about the same as that required for the moons of the giant planets about 400 km diameter a figure that would have suggested about 200 round objects in the Kuiper belt and thousands more beyond 52 53 Many astronomers argued that the public would not accept a definition creating a large number of planets 7 To acknowledge the problem the IAU set about creating the definition of planet and produced one in August 2006 Their definition dropped to the eight significantly larger bodies that had cleared their orbit Mercury Venus Earth Mars Jupiter Saturn Uranus and Neptune and a new class of dwarf planets was created initially containing three objects Ceres Pluto and Eris 54 This definition has not been universally used or accepted In planetary geology celestial objects have been assessed and defined as planets by geophysical characteristics Planetary scientists are more interested in planetary geology than dynamics so they classify planets based on their geological properties A celestial body may acquire a dynamic planetary geology at approximately the mass required for its mantle to become plastic under its own weight This leads to a state of hydrostatic equilibrium where the body acquires a stable round shape which is adopted as the hallmark of planethood by geophysical definitions For example 55 a substellar mass body that has never undergone nuclear fusion and has enough gravitation to be round due to hydrostatic equilibrium regardless of its orbital parameters 56 In the Solar System this mass is generally less than the mass required for a body to clear its orbit and thus some objects that are considered planets under geophysical definitions are not considered as such under the IAU definition such as Ceres and Pluto 3 Proponents of such definitions often argue that location should not matter and that planethood should be defined by the intrinsic properties of an object 3 Dwarf planets had been proposed as a category of small planet as opposed to planetoids as sub planetary objects and planetary geologists continue to treat them as planets despite the IAU definition 57 The largest known trans Neptunian objects with their moons the Earth and Moon have been added for comparison All pictures are artist s impressions except for the Pluto and Earth systems The number of dwarf planets even among known objects is not certain In 2019 Grundy et al argued based on the low densities of some mid sized trans Neptunian objects that the limiting size required for a trans Neptunian object to reach equilibrium was in fact much larger than it is for the icy moons of the giant planets being about 900 km diameter 57 There is general consensus on Ceres in the asteroid belt 58 and on the eight trans Neptunians that probably cross this threshold Quaoar Sedna Orcus Pluto Haumea Eris Makemake and Gonggong 59 Planetary geologists may include the twenty known planetary mass moons as satellite planets including Earth s Moon and Pluto s Charon like the early modern astronomers 3 60 Some go even further and include relatively large geologically evolved bodies that are nonetheless not very round today such as Pallas and Vesta 3 or rounded bodies that were completely disrupted by impacts and re accreted like Hygiea as planets 61 62 63 The 2006 IAU definition presents some challenges for exoplanets because the language is specific to the Solar System and the criteria of roundness and orbital zone clearance are not presently observable for exoplanets 64 There is no official definition of exoplanets but the IAU s working group on the topic adopted a provisional statement in 2018 Astronomer Jean Luc Margot proposed a mathematical criterion that determines whether an object can clear its orbit during the lifetime of its host star based on the mass of the planet its semimajor axis and the mass of its host star 65 The formula produces a value called p that is greater than 1 for planets a The eight known planets and all known exoplanets have p values above 100 while Ceres Pluto and Eris have p values of 0 1 or less Objects with p values of 1 or more are expected to be approximately spherical so that objects that fulfill the orbital zone clearance requirement automatically fulfill the roundness requirement 66 Definition and similar conceptsMain articles Definition of planet and IAU definition of planet Euler diagram showing the IAU Executive Committee conception of the types of bodies in the Solar System At the 2006 meeting of the IAU s General Assembly after much debate and one failed proposal the following definition was passed in a resolution voted for by a large majority of those remaining at the meeting addressing particularly the issue of the lower limits for a celestial object to be defined as a planet The 2006 resolution defines planets within the Solar System as follows 1 A planet 1 is a celestial body inside the Solar System that a is in orbit around the Sun b has sufficient mass for its self gravity to overcome rigid body forces so that it assumes a hydrostatic equilibrium nearly round shape and c has cleared the neighbourhood around its orbit 1 The eight planets are Mercury Venus Earth Mars Jupiter Saturn Uranus and Neptune Under this definition the Solar System is considered to have eight planets Bodies that fulfill the first two conditions but not the third are classified as dwarf planets provided they are not natural satellites of other planets Originally an IAU committee had proposed a definition that would have included a larger number of planets as it did not include c as a criterion 67 After much discussion it was decided via a vote that those bodies should instead be classified as dwarf planets 45 This definition is based in modern theories of planetary formation in which planetary embryos initially clear their orbital neighborhood of other smaller objects As described below planets form by material accreting together in a disk of matter surrounding a protostar This process results in a collection of relatively substantial objects each of which has either swept up or scattered away most of the material that had been orbiting near it These objects do not collide with one another because they are too far apart sometimes in orbital resonance 68 Exoplanet Main article Exoplanet Definition The 2006 IAU definition presents some challenges for exoplanets because the language is specific to the Solar System and the criteria of roundness and orbital zone clearance are not presently observable for exoplanets 64 The IAU working group on extrasolar planets WGESP issued a working definition in 2001 and amended it in 2003 69 In 2018 this definition was reassessed and updated as knowledge of exoplanets increased 69 The current official working definition of an exoplanet is as follows 70 Objects with true masses below the limiting mass for thermonuclear fusion of deuterium currently calculated to be 13 Jupiter masses for objects of solar metallicity that orbit stars brown dwarfs or stellar remnants and that have a mass ratio with the central object below the L4 L5 instability M Mcentral lt 2 25 621 are planets no matter how they formed The minimum mass size required for an extrasolar object to be considered a planet should be the same as that used in our Solar System Substellar objects with true masses above the limiting mass for thermonuclear fusion of deuterium are brown dwarfs no matter how they formed nor where they are located Free floating objects in young star clusters with masses below the limiting mass for thermonuclear fusion of deuterium are not planets but are sub brown dwarfs or whatever name is most appropriate 70 The IAU noted that this definition could be expected to evolve as knowledge improves 70 A 2022 review article discussing the history and rationale of this definition suggested that the words in young star clusters should be deleted in clause 3 as such objects have now been found elsewhere and that the term sub brown dwarfs should be replaced by the more current free floating planetary mass objects 69 Planetary mass object Main article Planetary mass object See also List of gravitationally rounded objects of the Solar System The planetary mass moons to scale compared with Mercury Venus Earth Mars and Pluto Borderline Proteus and Nereid about the same size as round Mimas have been included Unimaged Dysnomia intermediate in size between Tethys and Enceladus is not shown Geoscientists often reject the IAU definition preferring to consider round moons and dwarf planets as also being planets Some scientists who accept the IAU definition of planet use other terms for bodies satisfying geophysical planet definitions such as world 7 The term planetary mass object has also been used to refer to ambiguous situations concerning exoplanets such as objects with mass typical for a planet that are free floating or orbit a brown dwarf instead of a star 69 Mythology and namingSee also Weekday names and classical planet The names for the planets in the Western world are derived from the naming practices of the Romans which ultimately derive from those of the Greeks and the Babylonians In ancient Greece the two great luminaries the Sun and the Moon were called Helios and Selene two ancient Titanic deities the slowest planet Saturn was called Phainon the shiner followed by Phaethon Jupiter bright the red planet Mars was known as Pyroeis the fiery the brightest Venus was known as Phosphoros the light bringer and the fleeting final planet Mercury was called Stilbon the gleamer The Greeks assigned each planet to one among their pantheon of gods the Olympians and the earlier Titans 17 Helios and Selene were the names of both planets and gods both of them Titans later supplanted by Olympians Apollo and Artemis Phainon was sacred to Cronus the Titan who fathered the Olympians Phaethon was sacred to Zeus Cronus s son who deposed him as king Pyroeis was given to Ares son of Zeus and god of war Phosphoros was ruled by Aphrodite the goddess of love and Stilbon with its speedy motion was ruled over by Hermes messenger of the gods and god of learning and wit 17 The Greek practice of grafting their gods names onto the planets was almost certainly borrowed from the Babylonians The Babylonians named Venus after their goddess of love Ishtar Mars after their god of war Nergal Mercury after their god of wisdom Nabu and Jupiter after their chief god Marduk 71 There are too many concordances between Greek and Babylonian naming conventions for them to have arisen separately 17 Given the differences in mythology the correspondence was not perfect For instance the Babylonian Nergal was a god of war and thus the Greeks identified him with Ares Unlike Ares Nergal was also a god of pestilence and ruler of the underworld 72 73 74 The Greek gods of Olympus after whom the Solar System s Roman names of the planets are derived Today most people in the western world know the planets by names derived from the Olympian pantheon of gods Although modern Greeks still use their ancient names for the planets other European languages because of the influence of the Roman Empire and later the Catholic Church use the Roman Latin names rather than the Greek ones The Romans inherited Proto Indo European mythology as the Greeks did and shared with them a common pantheon under different names but the Romans lacked the rich narrative traditions that Greek poetic culture had given their gods During the later period of the Roman Republic Roman writers borrowed much of the Greek narratives and applied them to their own pantheon to the point where they became virtually indistinguishable 75 When the Romans studied Greek astronomy they gave the planets their own gods names Mercurius for Hermes Venus Aphrodite Mars Ares Iuppiter Zeus and Saturnus Cronus Some Romans following a belief possibly originating in Mesopotamia but developed in Hellenistic Egypt believed that the seven gods after whom the planets were named took hourly shifts in looking after affairs on Earth The order of shifts went Saturn Jupiter Mars Sun Venus Mercury Moon from the farthest to the closest planet 76 Therefore the first day was started by Saturn 1st hour second day by Sun 25th hour followed by Moon 49th hour Mars Mercury Jupiter and Venus Because each day was named by the god that started it this became the order of the days of the week in the Roman calendar 77 In English Saturday Sunday and Monday are straightforward translations of these Roman names The other days were renamed after Tiw Tuesday Wōden Wednesday THunor Thursday and Friġ Friday the Anglo Saxon gods considered similar or equivalent to Mars Mercury Jupiter and Venus respectively 78 Earth s name in English is not derived from Greco Roman mythology Because it was only generally accepted as a planet in the 17th century 34 there is no tradition of naming it after a god The same is true in English at least of the Sun and the Moon though they are no longer generally considered planets The name originates from the Old English word eorthe which was the word for ground and dirt as well as the world itself 79 As with its equivalents in the other Germanic languages it derives ultimately from the Proto Germanic word erthō as can be seen in the English earth the German Erde the Dutch aarde and the Scandinavian jord Many of the Romance languages retain the old Roman word terra or some variation of it that was used with the meaning of dry land as opposed to sea 80 The non Romance languages use their own native words The Greeks retain their original name Gh Ge 81 Non European cultures use other planetary naming systems India uses a system based on the Navagraha which incorporates the seven traditional planets Surya Sun Chandra Moon Budha for Mercury Shukra bright for Venus Mangala the god of war for Mars Bṛhaspati councilor of the gods for Jupiter and Shani symbolic of time for Saturn and the ascending and descending lunar nodes Rahu and Ketu 82 China and the countries of eastern Asia historically subject to Chinese cultural influence such as Japan Korea and Vietnam use a naming system based on the five Chinese elements water Mercury 水星 water star metal Venus 金星 metal star fire Mars 火星 fire star wood Jupiter 木星 wood star and earth Saturn 土星 earth star 77 The names of Uranus 天王星 sky king star Neptune 海王星 sea king star and Pluto 冥王星 underworld king star in Chinese Korean and Japanese are calques based on the roles of those gods in Roman and Greek mythology 83 84 b Chinese uses calques for the dwarf planets and many asteroids as well e g Eris 鬩神星 quarrel goddess star Ceres 穀神星 grain goddess star and Pallas 智神星 wisdom goddess star 83 In traditional Hebrew astronomy the seven traditional planets have for the most part descriptive names the Sun is חמה Ḥammah or the hot one the Moon is לבנה Levanah or the white one Venus is כוכב נוגה Kokhav Nogah or the bright planet Mercury is כוכב Kokhav or the planet given its lack of distinguishing features Mars is מאדים Ma adim or the red one and Saturn is שבתאי Shabbatai or the resting one in reference to its slow movement compared to the other visible planets 86 The odd one out is Jupiter called צדק Tzedeq or justice 86 Hebrew names were chosen for Uranus אורון Oron small light and Neptune רהב Rahab a Biblical sea monster in 2009 87 prior to that the names Uranus and Neptune had simply been borrowed 88 The etymologies for the Arabic names of the planets are less well understood Mostly agreed among scholars are Venus الزهرة az Zuhara the bright one 89 Earth الأرض al ʾArḍ from the same root as eretz and Saturn ز ح ل Zuḥal withdrawer 90 Multiple suggested etymologies exist for Mercury ع ط ار د ʿUṭarid Mars ا ل م ر يخ al Mirrikh and Jupiter المشتري al Mustari but there is no agreement among scholars 91 92 93 94 When subsequent planets were discovered in the 18th and 19th centuries Uranus was named for a Greek deity and Neptune for a Roman one the counterpart of Poseidon The asteroids were initially named from mythology as well Ceres Juno and Vesta are major Roman goddesses and Pallas is an epithet of the Greek goddess Athena but as more and more were discovered the mythological restriction was dropped starting from Massalia in 1852 95 Pluto was given a classical name as it was considered a major planet when it was discovered After more objects were discovered beyond Neptune naming conventions depending on their orbits were put in place those in the 2 3 resonance with Neptune the plutinos are given names from underworld myths while others are given names from creation myths Most of the trans Neptunian dwarf planets are named after gods and goddesses from other cultures e g Quaoar is named after a Tongva god except for Orcus and Eris which continued the Roman and Greek scheme 96 97 The moons including the planetary mass ones are generally given names with some association with their parent planet The planetary mass moons of Jupiter are named after four of Zeus lovers or other sexual partners those of Saturn are named after Cronus brothers and sisters the Titans those of Uranus are named after characters from Shakespeare and Pope originally specifically from fairy mythology 98 but that ended with the naming of Miranda Neptune s planetary mass moon Triton is named after the god s son Pluto s planetary mass moon Charon is named after the ferryman of the dead who carries the souls of the newly deceased to the underworld Pluto s domain and Eris only known moon Dysnomia is named after one of Eris daughters the spirit of lawlessness 99 Symbols Main article Planetary symbol Most common planetary symbols Sun Mercury Venus Earth Moon Mars Jupiter Saturn Uranus or Neptune The written symbols for Mercury Venus Jupiter Saturn and possibly Mars have been traced to forms found in late Greek papyrus texts 100 The symbols for Jupiter and Saturn are identified as monograms of the corresponding Greek names and the symbol for Mercury is a stylized caduceus 100 According to Annie Scott Dill Maunder antecedents of the planetary symbols were used in art to represent the gods associated with the classical planets Bianchini s planisphere discovered by Francesco Bianchini in the 18th century but produced in the 2nd century 101 shows Greek personifications of planetary gods charged with early versions of the planetary symbols Mercury has a caduceus Venus has attached to her necklace a cord connected to another necklace Mars a spear Jupiter a staff Saturn a scythe the Sun a circlet with rays radiating from it and the Moon a headdress with a crescent attached 102 The modern shapes with the cross marks first appeared around the 16th century According to Maunder the addition of crosses appears to be an attempt to give a savour of Christianity to the symbols of the old pagan gods 102 Earth itself was not considered a classical planet its symbol descends from a pre heliocentric symbol for the four corners of the world 103 When further planets were discovered orbiting the Sun symbols were invented for them The most common astronomical symbol for Uranus 104 was invented by Johann Gottfried Kohler and was intended to represent the newly discovered metal platinum 105 106 An alternative symbol was invented by Jerome Lalande and represents a globe with a H on top for Uranus discoverer Herschel 107 Today is mostly used by astronomers and by astrologers though it is possible to find each symbol in the other context 104 The first few asteroids were similarly given abstract symbols but as their number rose further and further this practice stopped in favour of numbering them instead 6 Neptune s symbol represents the god s trident 106 The astronomical symbol for Pluto is a P L monogram 108 though it has become less common since the IAU definition reclassified Pluto 109 Since Pluto s reclassification NASA has used the traditional astrological symbol of Pluto a planetary orb over Pluto s bident 109 Some rarer planetary symbols in Unicode Earth Vesta Ceres Pallas Hygiea Orcus Pluto or Haumea Quaoar Makemake Gonggong Eris Sedna The IAU discourages the use of planetary symbols in modern journal articles in favour of one letter or to disambiguate Mercury and Mars two letter abbreviations for the major planets The symbols for the Sun and Earth are nonetheless common as solar mass Earth mass and similar units are common in astronomy 110 Other planetary symbols today are mostly encountered in astrology Astrologers have started reusing the old astronomical symbols for the first few asteroids and continue to invent symbols for other objects though most proposed symbols are only used by their proposers 109 Unicode includes some relatively standard astrological symbols for some minor planets including the dwarf planets discovered in the 21st century though astronomical use of any of them is rare 109 111 FormationMain article Nebular hypothesis Artists impressions A protoplanetary disk Asteroids colliding during planet formation It is not known with certainty how planets are built The prevailing theory is that they are formed during the collapse of a nebula into a thin disk of gas and dust A protostar forms at the core surrounded by a rotating protoplanetary disk Through accretion a process of sticky collision dust particles in the disk steadily accumulate mass to form ever larger bodies Local concentrations of mass known as planetesimals form and these accelerate the accretion process by drawing in additional material by their gravitational attraction These concentrations become ever denser until they collapse inward under gravity to form protoplanets 112 After a planet reaches a mass somewhat larger than Mars mass it begins to accumulate an extended atmosphere 113 greatly increasing the capture rate of the planetesimals by means of atmospheric drag 114 115 Depending on the accretion history of solids and gas a giant planet an ice giant or a terrestrial planet may result 116 117 118 It is thought that the regular satellites of Jupiter Saturn and Uranus formed in a similar way 119 120 however Triton was likely captured by Neptune 121 and Earth s Moon 122 and Pluto s Charon might have formed in collisions 123 When the protostar has grown such that it ignites to form a star the surviving disk is removed from the inside outward by photoevaporation the solar wind Poynting Robertson drag and other effects 124 125 Thereafter there still may be many protoplanets orbiting the star or each other but over time many will collide either to form a larger combined protoplanet or release material for other protoplanets to absorb 126 Those objects that have become massive enough will capture most matter in their orbital neighbourhoods to become planets Protoplanets that have avoided collisions may become natural satellites of planets through a process of gravitational capture or remain in belts of other objects to become either dwarf planets or small bodies 127 128 Supernova remnant ejecta producing planet forming material The energetic impacts of the smaller planetesimals as well as radioactive decay will heat up the growing planet causing it to at least partially melt The interior of the planet begins to differentiate by density with higher density materials sinking toward the core 129 Smaller terrestrial planets lose most of their atmospheres because of this accretion but the lost gases can be replaced by outgassing from the mantle and from the subsequent impact of comets 130 Smaller planets will lose any atmosphere they gain through various escape mechanisms 131 With the discovery and observation of planetary systems around stars other than the Sun it is becoming possible to elaborate revise or even replace this account The level of metallicity an astronomical term describing the abundance of chemical elements with an atomic number greater than 2 helium appears to determine the likelihood that a star will have planets 132 133 Hence a metal rich population I star is more likely to have a substantial planetary system than a metal poor population II star 134 Solar SystemMain article Solar System The Solar System including the Sun planets dwarf planets and the larger moons Distances between the bodies are not to scale According to the IAU definition there are eight planets in the Solar System which are in increasing distance from the Sun 1 Mercury Venus Earth Mars Jupiter Saturn Uranus and Neptune Jupiter is the largest at 318 Earth masses whereas Mercury is the smallest at 0 055 Earth masses 135 The planets of the Solar System can be divided into categories based on their composition Terrestrials are similar to Earth with bodies largely composed of rock and metal Mercury Venus Earth and Mars Earth is the largest terrestrial planet 136 Giant planets are significantly more massive than the terrestrials Jupiter Saturn Uranus and Neptune 136 They differ from the terrestrial planets in composition The gas giants Jupiter and Saturn are primarily composed of hydrogen and helium and are the most massive planets in the Solar System Saturn is one third as massive as Jupiter at 95 Earth masses 137 The ice giants Uranus and Neptune are primarily composed of low boiling point materials such as water methane and ammonia with thick atmospheres of hydrogen and helium They have a significantly lower mass than the gas giants only 14 and 17 Earth masses 137 Dwarf planets are gravitationally rounded but have not cleared their orbits of other bodies In increasing order of average distance from the Sun the ones generally agreed among astronomers are Ceres Orcus Pluto Haumea Quaoar Makemake Gonggong Eris and Sedna 57 Ceres is the largest object in the asteroid belt located between the orbits of Mars and Jupiter The other eight all orbit beyond Neptune Orcus Pluto Haumea Quaoar and Makemake orbit in the Kuiper belt which is a second belt of small Solar System bodies beyond the orbit of Neptune Gonggong and Eris orbit in the scattered disc which is somewhat further out and unlike the Kuiper belt is unstable towards interactions with Neptune Sedna is the largest known detached object a population that never comes close enough to the Sun to interact with any of the classical planets the origins of their orbits are still being debated All nine are similar to terrestrial planets in having a solid surface but they are made of ice and rock rather than rock and metal Moreover all of them are smaller than Mercury with Pluto being the largest known dwarf planet and Eris being the most massive known 138 139 There are at least twenty planetary mass moons or satellite planets moons large enough to take on ellipsoidal shapes though Dysnomia s shape has never been measured it is massive and dense enough to be a solid body The twenty generally agreed are as follows 3 140 One satellite of Earth the Moon Four satellites of Jupiter Io Europa Ganymede and Callisto Seven satellites of Saturn Mimas Enceladus Tethys Dione Rhea Titan and Iapetus Five satellites of Uranus Miranda Ariel Umbriel Titania and Oberon One satellite of Neptune Triton One satellite of Pluto Charon One satellite of Eris DysnomiaThe Moon Io and Europa have compositions similar to the terrestrial planets the others are made of ice and rock like the dwarf planets with Tethys being made of almost pure ice Europa is often considered an icy planet though because its surface ice layer makes it difficult to study its interior 3 141 Ganymede and Titan are larger than Mercury by radius and Callisto almost equals it but all three are much less massive Mimas is the smallest object generally agreed to be a geophysical planet at about six millionths of Earth s mass though there are many larger bodies that may not be geophysical planets e g Salacia 57 Planetary attributes The tables below summarise some properties of objects generally agreed to satisfy geophysical planet definitions There are many smaller dwarf planet candidates such as Salacia that have not been included in the tables because astronomers disagree on whether or not they are dwarf planets The diameters masses orbital periods and rotation periods of the major planets are available from the Jet Propulsion Laboratory 135 JPL also provides their semi major axes inclinations and eccentricities of planetary orbits 142 and the axial tilts are taken from their Horizons database 143 Other information is summarized by NASA 144 The data for the dwarf planets and planetary mass moons is taken from list of gravitationally rounded objects of the Solar System with sources listed there Name Equatorialdiameter Mass Semi major axis AU Orbital period years Inclinationto the ecliptic Orbitaleccentricity Rotation period days Confirmedmoons Axial tilt Rings AtmosphereMajor planets Mercury 0 383 0 06 0 39 0 24 7 00 0 206 58 65 0 0 04 no minimal Venus 0 949 0 81 0 72 0 62 3 39 0 007 243 02 0 177 30 no CO2 N2 Earth 1 000 1 00 1 00 1 00 0 0 0 017 1 00 1 23 44 no N2 O2 Ar Mars 0 532 0 11 1 52 1 88 1 85 0 093 1 03 2 25 19 no CO2 N2 Ar Jupiter 11 209 317 83 5 20 11 86 1 30 0 048 0 41 84 3 13 yes H2 He Saturn 9 449 95 16 9 54 29 45 2 49 0 054 0 44 83 26 73 yes H2 He Uranus 4 007 14 54 19 19 84 02 0 773 0 047 0 72 27 97 77 yes H2 He CH4 Neptune 3 883 17 15 30 07 164 79 1 77 0 009 0 67 14 28 32 yes H2 He CH4Dwarf planets Ceres 0 0742 0 00016 2 77 4 60 10 59 0 080 0 38 0 4 no minimal Orcus 0 072 0 0001 39 42 247 5 20 59 0 226 1 Pluto 0 186 0 0022 39 48 247 9 17 14 0 249 6 39 5 119 6 no N2 CH4 CO Haumea 0 13 0 0007 43 34 283 8 28 21 0 195 0 16 2 126 yes Quaoar 0 087 0 0003 43 69 288 0 7 99 0 038 0 37 1 Makemake 0 11 0 0005 45 79 306 2 28 98 0 161 0 95 1 minimal Gonggong 0 10 0 0003 67 33 552 5 30 74 0 506 0 93 1 Eris 0 18 0 0028 67 67 559 44 04 0 436 15 79 1 78 Sedna 0 078 525 86 12059 11 93 0 855 0 43 0 Color legend terrestrial planets gas giants ice giants both are giant planets dwarf planets Measured relative to Earth The Earth s mass is approximately 5 972 1024 kilograms and its equatorial radius is approximately 6 378 kilometres 135 As all the planetary mass moons exhibit synchronous rotation their rotation periods equal their orbital periods Planetary mass moonsName Equatorialdiameter Mass Semi major axis km Orbital period days Inclinationto primary s equator Orbitaleccentricity Axial tilt Atmosphere Moon 0 272 0 0123 384 399 27 322 18 29 28 58 0 0549 6 68 minimal 1 Io 0 285 0 0150 421 600 1 769 0 04 0 0041 0 minimal 2 Europa 0 246 0 00804 670 900 3 551 0 47 0 009 0 1 minimal 3 Ganymede 0 413 0 0248 1 070 400 7 155 1 85 0 0013 0 2 minimal 4 Callisto 0 378 0 0180 1 882 700 16 689 0 2 0 0074 0 2 minimal 1 Mimas 0 031 0 00000628 185 520 0 942 1 51 0 0202 0 2 Enceladus 0 04 0 0000181 237 948 1 370 0 02 0 0047 0 minimal 3 Tethys 0 084 0 000103 294 619 1 888 1 51 0 02 0 4 Dione 0 088 0 000183 377 396 2 737 0 019 0 002 0 minimal 5 Rhea 0 12 0 000386 527 108 4 518 0 345 0 001 0 minimal 6 Titan 0 404 0 0225 1 221 870 15 945 0 33 0 0288 0 3 N2 CH4 8 Iapetus 0 115 0 000302 3 560 820 79 322 14 72 0 0286 0 5 Miranda 0 037 0 0000110 129 390 1 414 4 22 0 0013 0 1 Ariel 0 091 0 000226 190 900 2 520 0 31 0 0012 0 2 Umbriel 0 092 0 00020 266 000 4 144 0 36 0 005 0 3 Titania 0 124 0 00059 436 300 8 706 0 14 0 0011 0 4 Oberon 0 119 0 000505 583 519 13 46 0 10 0 0014 0 1 Triton 0 212 0 00358 354 759 5 877 157 0 00002 0 7 N2 CH4 1 Charon 0 095 0 000255 17 536 6 387 0 001 0 0022 0 1 Dysnomia 0 057 0 00005 0 00008 37 300 15 786 0 0 0062 0Color legend predominantly rocky predominantly icy Measured relative to Earth ExoplanetsMain article Exoplanet Exoplanet detections per year as of June 2022 by NASA Exoplanet Archive 145 An exoplanet extrasolar planet is a planet outside the Solar System As of 1 January 2023 there are 5 297 confirmed exoplanets in 3 904 planetary systems with 850 systems having more than one planet 146 Known exoplanets range in size from gas giants about twice as large as Jupiter down to just over the size of the Moon Analysis of gravitational microlensing data suggests a minimum average of 1 6 bound planets for every star in the Milky Way 147 In early 1992 radio astronomers Aleksander Wolszczan and Dale Frail announced the discovery of two planets orbiting the pulsar PSR 1257 12 46 This discovery was confirmed and is generally considered to be the first definitive detection of exoplanets Researchers suspect they formed from a disk remnant left over from the supernova that produced the pulsar 148 The first confirmed discovery of an extrasolar planet orbiting an ordinary main sequence star occurred on 6 October 1995 when Michel Mayor and Didier Queloz of the University of Geneva announced the detection of 51 Pegasi b an exoplanet around 51 Pegasi 149 From then until the Kepler mission most known extrasolar planets were gas giants comparable in mass to Jupiter or larger as they were more easily detected The catalog of Kepler candidate planets consists mostly of planets the size of Neptune and smaller down to smaller than Mercury 150 151 In 2011 the Kepler Space Telescope team reported the discovery of the first Earth sized extrasolar planets orbiting a Sun like star Kepler 20e and Kepler 20f 152 153 154 Since that time more than 100 planets have been identified that are approximately the same size as Earth 20 of which orbit in the habitable zone of their star the range of orbits where a terrestrial planet could sustain liquid water on its surface given enough atmospheric pressure 155 156 157 One in five Sun like stars is thought to have an Earth sized planet in its habitable zone which suggests that the nearest would be expected to be within 12 light years distance from Earth c The frequency of occurrence of such terrestrial planets is one of the variables in the Drake equation which estimates the number of intelligent communicating civilizations that exist in the Milky Way 160 There are types of planets that do not exist in the Solar System super Earths and mini Neptunes which have masses between that of Earth and Neptune Such planets could be rocky like Earth or a mixture of volatiles and gas like Neptune the dividing line between the two possibilities is currently thought to occur at about twice the mass of Earth 161 The planet Gliese 581c with mass 5 5 10 4 times the mass of Earth 162 attracted attention upon its discovery for potentially being in the habitable zone 163 though later studies concluded that it is actually too close to its star to be habitable 164 Exoplanets have been found that are much closer to their parent star than any planet in the Solar System is to the Sun Mercury the closest planet to the Sun at 0 4 AU takes 88 days for an orbit but ultra short period planets can orbit in less than a day The Kepler 11 system has five of its planets in shorter orbits than Mercury s all of them much more massive than Mercury There are hot Jupiters such as 51 Pegasi b 149 that orbit very close to their star and may evaporate to become chthonian planets which are the leftover cores There are also exoplanets that are much farther from their star Neptune is 30 AU from the Sun and takes 165 years to orbit but there are exoplanets that are thousands of AU from their star and take more than a million years to orbit e g COCONUTS 2b 165 AttributesAlthough each planet has unique physical characteristics a number of broad commonalities do exist among them Some of these characteristics such as rings or natural satellites have only as yet been observed in planets in the Solar System whereas others are commonly observed in extrasolar planets 166 Dynamic characteristics Orbit Main articles Orbit and orbital elements See also Kepler s laws of planetary motion and Exoplanetology Orbital parameters The orbit of the planet Neptune compared to that of Pluto Note the elongation of Pluto s orbit in relation to Neptune s eccentricity as well as its large angle to the ecliptic inclination In the Solar System all the planets orbit the Sun in the same direction as the Sun rotates counter clockwise as seen from above the Sun s north pole At least one extrasolar planet WASP 17b has been found to orbit in the opposite direction to its star s rotation 167 The period of one revolution of a planet s orbit is known as its sidereal period or year 168 A planet s year depends on its distance from its star the farther a planet is from its star the longer the distance it must travel and the slower its speed since it is less affected by its star s gravity No planet s orbit is perfectly circular and hence the distance of each from the host star varies over the course of its year The closest approach to its star is called its periastron or perihelion in the Solar System whereas its farthest separation from the star is called its apastron aphelion As a planet approaches periastron its speed increases as it trades gravitational potential energy for kinetic energy just as a falling object on Earth accelerates as it falls As the planet nears apastron its speed decreases just as an object thrown upwards on Earth slows down as it reaches the apex of its trajectory 169 Each planet s orbit is delineated by a set of elements The eccentricity of an orbit describes the elongation of a planet s elliptical oval orbit Planets with low eccentricities have more circular orbits whereas planets with high eccentricities have more elliptical orbits The planets and large moons in the Solar System have relatively low eccentricities and thus nearly circular orbits 168 The comets and many Kuiper belt objects as well as several extrasolar planets have very high eccentricities and thus exceedingly elliptical orbits 170 171 The semi major axis gives the size of the orbit It is the distance from the midpoint to the longest diameter of its elliptical orbit This distance is not the same as its apastron because no planet s orbit has its star at its exact centre 168 The inclination of a planet tells how far above or below an established reference plane its orbit is tilted In the Solar System the reference plane is the plane of Earth s orbit called the ecliptic For extrasolar planets the plane known as the sky plane or plane of the sky is the plane perpendicular to the observer s line of sight from Earth 172 The eight planets of the Solar System all lie very close to the ecliptic comets and Kuiper belt objects like Pluto are at far more extreme angles to it 173 The large moons are generally not very inclined to their parent planets equators but Earth s Moon Saturn s Iapetus and Neptune s Triton are exceptions Triton is unique among the large moons in that it orbits retrograde i e in the direction opposite to its parent planet s rotation 174 The points at which a planet crosses above and below its reference plane are called its ascending and descending nodes 168 The longitude of the ascending node is the angle between the reference plane s 0 longitude and the planet s ascending node The argument of periapsis or perihelion in the Solar System is the angle between a planet s ascending node and its closest approach to its star 168 Axial tilt Main article Axial tilt Earth s axial tilt is about 23 4 It oscillates between 22 1 and 24 5 on a 41 000 year cycle and is currently decreasing Planets have varying degrees of axial tilt they spin at an angle to the plane of their stars equators This causes the amount of light received by each hemisphere to vary over the course of its year when the northern hemisphere points away from its star the southern hemisphere points towards it and vice versa Each planet therefore has seasons resulting in changes to the climate over the course of its year The time at which each hemisphere points farthest or nearest from its star is known as its solstice Each planet has two in the course of its orbit when one hemisphere has its summer solstice with its day being the longest the other has its winter solstice when its day is shortest The varying amount of light and heat received by each hemisphere creates annual changes in weather patterns for each half of the planet Jupiter s axial tilt is very small so its seasonal variation is minimal Uranus on the other hand has an axial tilt so extreme it is virtually on its side which means that its hemispheres are either continually in sunlight or continually in darkness around the time of its solstices 175 Among extrasolar planets axial tilts are not known for certain though most hot Jupiters are believed to have a negligible axial tilt as a result of their proximity to their stars 176 Rotation See also Exoplanetology Rotation and axial tilt The planets rotate around invisible axes through their centres A planet s rotation period is known as a stellar day Most of the planets in the Solar System rotate in the same direction as they orbit the Sun which is counter clockwise as seen from above the Sun s north pole The exceptions are Venus 177 and Uranus 178 which rotate clockwise though Uranus s extreme axial tilt means there are differing conventions on which of its poles is north and therefore whether it is rotating clockwise or anti clockwise 179 Regardless of which convention is used Uranus has a retrograde rotation relative to its orbit 178 Comparison of the rotation period sped up 10 000 times negative values denoting retrograde flattening and axial tilt of the planets and the Moon SVG animation The rotation of a planet can be induced by several factors during formation A net angular momentum can be induced by the individual angular momentum contributions of accreted objects The accretion of gas by the giant planets contributes to the angular momentum Finally during the last stages of planet building a stochastic process of protoplanetary accretion can randomly alter the spin axis of the planet 180 There is great variation in the length of day between the planets with Venus taking 243 days to rotate and the giant planets only a few hours 144 The rotational periods of extrasolar planets are not known but for hot Jupiters their proximity to their stars means that they are tidally locked that is their orbits are in sync with their rotations This means they always show one face to their stars with one side in perpetual day the other in perpetual night 181 Mercury and Venus the closest planets to the Sun similarly exhibit very slow rotation Mercury is tidally locked into a 3 2 spin orbit resonance rotating three times for every two revolutions around the Sun 182 and Venus rotation may be in equilibrium between tidal forces slowing it down and atmospheric tides created by solar heating speeding it up 183 184 All the large moons are tidally locked to their parent planets 185 Pluto and Charon are tidally locked to each other 186 as are Eris and Dysnomia 140 The other dwarf planets with known rotation periods rotate faster than Earth Haumea rotates so fast that it has been distorted into a triaxial ellipsoid 187 The exoplanet Tau Bootis b and its parent star Tau Bootis appear to be mutually tidally locked 188 189 Orbital clearing Main article Clearing the neighbourhood The defining dynamic characteristic of a planet according to the IAU definition is that it has cleared its neighborhood A planet that has cleared its neighborhood has accumulated enough mass to gather up or sweep away all the planetesimals in its orbit In effect it orbits its star in isolation as opposed to sharing its orbit with a multitude of similar sized objects As described above this characteristic was mandated as part of the IAU s official definition of a planet in August 2006 1 Although to date this criterion only applies to the Solar System a number of young extrasolar systems have been found in which evidence suggests orbital clearing is taking place within their circumstellar discs 190 Physical characteristics Size and shape See also Earth Size and shape Astronomical body Size and Planetary coordinate system Gravity causes planets to be pulled into a roughly spherical shape so a planet s size can be expressed roughly by an average radius for example Earth radius or Jupiter radius However planets are not perfectly spherical for example the Earth s rotation causes it to be slightly flattened at the poles with a bulge around the equator 191 Therefore a better approximation of Earth s shape is an oblate spheroid whose equatorial diameter is 43 kilometers 27 mi larger than the pole to pole diameter 192 Generally a planet s shape may be described by giving polar and equatorial radii of a spheroid or specifying a reference ellipsoid From such a specification the planet s flattening surface area and volume can be calculated its normal gravity can be computed knowing its size shape rotation rate and mass 193 Mass Main article Planetary mass A planet s defining physical characteristic is that it is massive enough for the force of its own gravity to dominate over the electromagnetic forces binding its physical structure leading to a state of hydrostatic equilibrium This effectively means that all planets are spherical or spheroidal Up to a certain mass an object can be irregular in shape but beyond that point which varies depending on the chemical makeup of the object gravity begins to pull an object towards its own centre of mass until the object collapses into a sphere 194 Mass is the prime attribute by which planets are distinguished from stars While the lower stellar mass limit is estimated to be around 75 times that of Jupiter MJ the upper planetary mass limit for planethood is only roughly 13 MJ for objects with solar type isotopic abundance beyond which it achieves conditions suitable for nuclear fusion of deuterium Other than the Sun no objects of such mass exist in the Solar System but there are exoplanets of this size The 13 MJ limit is not universally agreed upon and the Extrasolar Planets Encyclopaedia includes objects up to 60 MJ 195 and the Exoplanet Data Explorer up to 24 MJ 196 The smallest known exoplanet with an accurately known mass is PSR B1257 12A one of the first extrasolar planets discovered which was found in 1992 in orbit around a pulsar Its mass is roughly half that of the planet Mercury 197 Even smaller is WD 1145 017 b orbiting a white dwarf its mass is roughly that of the dwarf planet Haumea and it is typically termed a minor planet 198 The smallest known planet orbiting a main sequence star other than the Sun is Kepler 37b with a mass and radius that is probably slightly higher than that of the Moon 151 Internal differentiation Main article Planetary differentiation Illustration of the interior of Jupiter with a rocky core overlaid by a deep layer of metallic hydrogen Every planet began its existence in an entirely fluid state in early formation the denser heavier materials sank to the centre leaving the lighter materials near the surface Each therefore has a differentiated interior consisting of a dense planetary core surrounded by a mantle that either is or was a fluid The terrestrial planets mantles are sealed within hard crusts 199 but in the giant planets the mantle simply blends into the upper cloud layers The terrestrial planets have cores of elements such as iron and nickel and mantles of silicates Jupiter and Saturn are believed to have cores of rock and metal surrounded by mantles of metallic hydrogen 200 Uranus and Neptune which are smaller have rocky cores surrounded by mantles of water ammonia methane and other ices 201 The fluid action within these planets cores creates a geodynamo that generates a magnetic field 199 Similar differentiation processes are believed to have occurred on some of the large moons and dwarf planets 57 though the process may not always have been completed Ceres Callisto and Titan appear to be incompletely differentiated 202 203 Atmosphere Main articles Atmosphere and extraterrestrial atmospheres See also Extraterrestrial skies Earth s atmosphere All of the Solar System planets except Mercury 204 have substantial atmospheres because their gravity is strong enough to keep gases close to the surface Saturn s largest moon Titan also has a substantial atmosphere thicker than that of Earth 205 Neptune s largest moon Triton 206 and the dwarf planet Pluto have more tenuous atmospheres 207 The larger giant planets are massive enough to keep large amounts of the light gases hydrogen and helium whereas the smaller planets lose these gases into space 208 The composition of Earth s atmosphere is different from the other planets because the various life processes that have transpired on the planet have introduced free molecular oxygen 209 Planetary atmospheres are affected by the varying insolation or internal energy leading to the formation of dynamic weather systems such as hurricanes on Earth planet wide dust storms on Mars a greater than Earth sized anticyclone on Jupiter called the Great Red Spot and holes in the atmosphere on Neptune 175 Weather patterns detected on exoplanets include a hot region on HD 189733 b twice the size of the Great Red Spot 210 as well as clouds on the hot Jupiter Kepler 7b 211 the super Earth Gliese 1214 b and others 212 213 Hot Jupiters due to their extreme proximities to their host stars have been shown to be losing their atmospheres into space due to stellar radiation much like the tails of comets 214 215 These planets may have vast differences in temperature between their day and night sides that produce supersonic winds 216 although multiple factors are involved and the details of the atmospheric dynamics that affect the day night temperature difference are complex 217 218 Magnetosphere Main article Magnetosphere Earth s magnetosphere diagram One important characteristic of the planets is their intrinsic magnetic moments which in turn give rise to magnetospheres The presence of a magnetic field indicates that the planet is still geologically alive In other words magnetized planets have flows of electrically conducting material in their interiors which generate their magnetic fields These fields significantly change the interaction of the planet and solar wind A magnetized planet creates a cavity in the solar wind around itself called the magnetosphere which the wind cannot penetrate The magnetosphere can be much larger than the planet itself In contrast non magnetized planets have only small magnetospheres induced by interaction of the ionosphere with the solar wind which cannot effectively protect the planet 219 Of the eight planets in the Solar System only Venus and Mars lack such a magnetic field 219 Of the magnetized planets the magnetic field of Mercury is the weakest and is barely able to deflect the solar wind Jupiter s moon Ganymede has a magnetic field several times stronger and Jupiter s is the strongest in the Solar System so intense in fact that it poses a serious health risk to future crewed missions to all its moons inward of Callisto 220 The magnetic fields of the other giant planets measured at their surfaces are roughly similar in strength to that of Earth but their magnetic moments are significantly larger The magnetic fields of Uranus and Neptune are strongly tilted relative to the planets rotational axes and displaced from the planets centres 219 In 2003 a team of astronomers in Hawaii observing the star HD 179949 detected a bright spot on its surface apparently created by the magnetosphere of an orbiting hot Jupiter 221 222 Secondary characteristics Main articles Natural satellite and planetary ring The rings of Saturn Several planets or dwarf planets in the Solar System such as Neptune and Pluto have orbital periods that are in resonance with each other or with smaller bodies This is common in satellite systems e g the resonance between Io Europa and Ganymede around Jupiter or between Enceladus and Dione around Saturn All except Mercury and Venus have natural satellites often called moons Earth has one Mars has two and the giant planets have numerous moons in complex planetary type systems Except for Ceres and Sedna all the consensus dwarf planets are known to have at least one moon as well Many moons of the giant planets have features similar to those on the terrestrial planets and dwarf planets and some have been studied as possible abodes of life especially Europa and Enceladus 223 224 225 226 227 The four giant planets are orbited by planetary rings of varying size and complexity The rings are composed primarily of dust or particulate matter but can host tiny moonlets whose gravity shapes and maintains their structure Although the origins of planetary rings is not precisely known they are believed to be the result of natural satellites that fell below their parent planet s Roche limit and were torn apart by tidal forces 228 229 The dwarf planet Haumea also has a ring 230 No secondary characteristics have been observed around extrasolar planets The sub brown dwarf Cha 110913 773444 which has been described as a rogue planet is believed to be orbited by a tiny protoplanetary disc 231 and the sub brown dwarf OTS 44 was shown to be surrounded by a substantial protoplanetary disk of at least 10 Earth masses 232 See alsoDouble planet A binary system where two planetary mass objects share an orbital axis external to both List of landings on extraterrestrial bodies Lists of planets A list of lists of planets sorted by diverse attributes Mesoplanet Planetary objects that have a mass smaller than Mercury but larger than Ceres Planetary habitability Known extent to which a planet is suitable for life Planetary mnemonic Phrase used to remember the names of planets Theoretical planetology Scientific modeling of planetsNotes Margot s parameter 66 is not to be confused with the famous mathematical constant p 3 14159265 In Vietnamese calques are more common than directly reading these names as Sino Vietnamese e g sao Thuỷ rather than Thuỷ tinh for Mercury Pluto is not sao Minh Vương but sao Diem Vương Yama star 85 Here Earth sized means 1 2 Earth radii and habitable zone means the region with 0 25 to 4 times Earth s stellar flux corresponding to 0 5 2 AU for the Sun Data for G type stars like the Sun is not available This statistic is an extrapolation from data on K type stars 158 159 References a b c d IAU 2006 General Assembly Result of the IAU Resolution votes International Astronomical Union 2006 Retrieved 30 December 2009 Working Group on Extrasolar Planets WGESP of the International Astronomical Union IAU 2001 Archived from the original on 16 September 2006 Retrieved 23 August 2008 a b c d e f g Lakdawalla Emily 21 April 2020 What Is A Planet The Planetary Society Archived from the original on 22 January 2022 Retrieved 3 April 2022 Grossman Lisa 24 August 2021 The definition of planet is still a sore point especially among Pluto fans Science News What is a Planet Planets NASA Solar System Exploration Retrieved 2 May 2022 a b c d Hilton James L 17 September 2001 When Did the Asteroids Become Minor Planets U S Naval Observatory Archived from the original on 21 September 2007 Retrieved 8 April 2007 a b c d e f g h Metzger Philip T Grundy W M Sykes Mark V Stern Alan Bell III James F Detelich Charlene E Runyon Kirby Summers Michael 2022 Moons are planets Scientific usefulness versus cultural teleology in the taxonomy of planetary science Icarus 374 114768 arXiv 2110 15285 Bibcode 2022Icar 37414768M doi 10 1016 j icarus 2021 114768 S2CID 240071005 Retrieved 8 August 2022 Ancient Greek Astronomy and Cosmology The Library of Congress Retrieved 19 May 2016 planhs planhths Liddell Henry George Scott Robert A Greek English Lexicon at the Perseus Project Retrieved on 11 July 2022 Definition of planet Merriam Webster OnLine Retrieved 23 July 2007 Planet Etymology dictionary com Retrieved 29 June 2015 a b planet n Oxford English Dictionary 2007 Retrieved 7 February 2008 Note select the Etymology tab Neugebauer Otto E 1945 The History of Ancient Astronomy Problems and Methods Journal of Near Eastern Studies 4 1 1 38 doi 10 1086 370729 S2CID 162347339 Ronan Colin 1996 Astronomy Before the Telescope In Walker Christopher ed Astronomy in China Korea and Japan British Museum Press pp 264 265 Kuhn Thomas S 1957 The Copernican Revolution Harvard University Press pp 5 20 ISBN 978 0 674 17103 9 a b Frautschi Steven C Olenick Richard P Apostol Tom M Goodstein David L 2007 The Mechanical Universe Mechanics and Heat Advanced ed Cambridge Cambridgeshire Cambridge University Press p 58 ISBN 978 0 521 71590 4 OCLC 227002144 a b c d e Evans James 1998 The History and Practice of Ancient Astronomy Oxford University Press pp 296 297 ISBN 978 0 19 509539 5 Retrieved 4 February 2008 Rochberg Francesca 2000 Astronomy and Calendars in Ancient Mesopotamia In Jack Sasson ed Civilizations of the Ancient Near East Vol III p 1930 Aaboe Asger 1991 The culture of Babylonia Babylonian mathematics astrology and astronomy in Boardman John Edwards I E S Hammond N G L Sollberger E 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