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Wednesday, March 4, 2015

Comet


From Wikipedia, the free encyclopedia

Comet Tempel collides with Deep Impact's impactorComet 67P/Churyumov–Gerasimenko orbited by Rosetta Comet Lovejoy seen from orbit
Comet Wild 2 visited by Stardust probeComet 17P/Holmes and its blue ionized tail
Comets – nucleus, coma and tail (clockwise from top left)
 · Comet 9P/Tempel collides with Deep Impact's impactor
 · Comet 67P/Churyumov–Gerasimenko orbited by Rosetta
 · Comet C/2011 W3 (Lovejoy) from orbit
 · Comet 17P/Holmes and its blue ionized tail
 · Comet 81P/Wild (Wild 2) visited by Stardust, 2004

A comet is an icy small Solar System body that, when passing close to the Sun, heats up and begins to outgas, displaying a visible atmosphere or coma, and sometimes also a tail. These phenomena are due to the effects of solar radiation and the solar wind upon the nucleus of the comet. Comet nuclei range from a few hundred metres to tens of kilometres across and are composed of loose collections of ice, dust, and small rocky particles. The coma and tail are much larger and, if sufficiently bright, may be seen from the Earth without the aid of a telescope. Comets have been observed and recorded since ancient times by many cultures.

Comets have a wide range of orbital periods, ranging from several years to several millions of years. Short-period comets originate in the Kuiper belt or its associated scattered disc, which lie beyond the orbit of Neptune. Longer-period comets are thought to originate in the Oort cloud, a spherical cloud of icy bodies extending from outside the Kuiper Belt to halfway to the next nearest star. Long-period comets are directed towards the Sun from the Oort cloud by gravitational perturbations caused by passing stars and the galactic tide. Hyperbolic comets may pass once through the inner Solar System before being flung out to interstellar space along hyperbolic trajectories.

Comets are distinguished from asteroids by the presence of an extended, gravitationally unbound atmosphere surrounding their central nucleus. This atmosphere has parts termed the coma (the central atmosphere immediately surrounding the nucleus) and the tail (a typically linear section consisting of dust or gas blown out from the coma by the Sun's light pressure or outstreaming solar wind plasma). However, extinct comets that have passed close to the Sun many times have lost nearly all of their volatile ices and dust and may come to resemble small asteroids.[1] Asteroids are thought to have a different origin from comets, having formed inside the orbit of Jupiter rather than in the outer Solar System.[2][3] The discovery of main-belt comets and active centaurs has blurred the distinction between asteroids and comets.

As of November 2014 there are 5,253 known comets,[4] a number which is steadily increasing. However, this represents only a tiny fraction of the total potential comet population, as the reservoir of comet-like bodies in the outer Solar System (in the Oort cloud) is estimated to be one trillion.[5][6] Roughly one comet per year is visible to the naked eye, though many of these are faint and unspectacular.[7] Particularly bright examples are called "Great Comets". Comets have been visited by unmanned probes such as the European Space Agency's Rosetta, which became the first ever to land a robotic spacecraft on a comet,[8] and NASA's Deep Impact, which blasted a crater on Comet Tempel 1 to study its interior.

Etymology

The word comet derives from the Old English cometa from the Latin comēta or comētēs. That, in turn, is a latinisation of the Greek κομήτης ("wearing long hair"), and the Oxford English Dictionary notes that the term (ἀστὴρ) κομήτης already meant "long-haired star, comet" in Greek. Κομήτης was derived from κομᾶν ("to wear the hair long"), which was itself derived from κόμη ("the hair of the head") and was used to mean "the tail of a comet".[9][10]

The astronomical symbol for comets is (), consisting of a small disc with three hairlike extensions.[11]

Physical characteristics

Nucleus


Nucleus of Comet 103P/Hartley as imaged during a spacecraft flyby. The nucleus is about 2 km in length.
Comet Borrelly exhibits jets, but has no surface ice.
Comet Wild 2 exhibits jets on light side and dark side, stark relief, and is dry.

The solid, core structure of a comet is known as the nucleus. Cometary nuclei are composed of an amalgamation of rock, dust, water ice, and frozen gases such as carbon dioxide, carbon monoxide, methane, and ammonia.[12] As such, they are popularly described as "dirty snowballs" after Fred Whipple's model.[13] However, some comets may have a higher dust content, leading them to be called "icy dirtballs".[14] Research conducted in 2014 suggests that comets are like "deep fried ice cream", in that their surfaces are formed of dense crystalline ice mixed with organic compounds, while the interior ice is colder and less dense.[15]

The surface of the nucleus is generally dry, dusty or rocky, suggesting that the ices are hidden beneath a surface crust several metres thick. In addition to the gases already mentioned, the nuclei contain a variety of organic compounds, which may include methanol, hydrogen cyanide, formaldehyde, ethanol, and ethane and perhaps more complex molecules such as long-chain hydrocarbons and amino acids.[16][17] In 2009, it was confirmed that the amino acid glycine had been found in the comet dust recovered by NASA's Stardust mission.[18] In August 2011, a report, based on NASA studies of meteorites found on Earth, was published suggesting DNA and RNA components (adenine, guanine, and related organic molecules) may have been formed on asteroids and comets.[19][20]

The outer surfaces of cometary nuclei have a very low albedo, making them among the least reflective objects found in the Solar System. The Giotto space probe found that the nucleus of Halley's Comet reflects about four percent of the light that falls on it,[21] and Deep Space 1 discovered that Comet Borrelly's surface reflects less than 3.0% of the light that falls on it;[21] by comparison, asphalt reflects seven percent of the light that falls on it. The dark surface material of the nucleus may consist of complex organic compounds. Solar heating drives off lighter volatile compounds, leaving behind larger organic compounds that tend to be very dark, like tar or crude oil. The low reflectivity of cometary surfaces enables them to absorb the heat necessary to drive their outgassing processes.[22]

Comet nuclei with radii of up to 30 kilometres (19 mi) have been observed,[23] but ascertaining their exact size is difficult.[24] The nucleus of P/2007 R5 is probably only 100–200 metres in diameter.[25] A lack of smaller comets being detected despite the increased sensitivity of instruments has led some to suggest that there is a real lack of comets smaller than 100 metres (330 ft) across.[26] Known comets have been estimated to have an average density of 0.6 g/cm3.[27] Because of their low mass, comet nuclei do not become spherical under their own gravity and therefore have irregular shapes.[28]

Roughly six percent of the near-Earth asteroids are thought to be extinct nuclei of comets that no longer experience outgassing,[29] including 14827 Hypnos and 3552 Don Quixote.

Properties of some comets
Name Dimensions
(km)
Density
(g/cm3)
Mass
(kg)[30]
Refs
Halley's Comet 15 × 8 × 8 0.6 3×1014 [31][32]
Tempel 1 7.6 × 4.9 0.62 7.9×1013 [33][27]
19P/Borrelly 8 × 4 × 4 0.3 2.0×1013 [27]
81P/Wild 5.5 × 4.0 × 3.3 0.6 2.3×1013 [34][27]
67P/Churyumov–Gerasimenko 4.1 × 3.3 × 1.8 0.47 1.0×1013 [35][36]

Coma


Hubble image of Comet ISON shortly before perihelion.[37]

The streams of dust and gas thus released form a huge and extremely thin atmosphere around the comet called the "coma", and the force exerted on the coma by the Sun's radiation pressure and solar wind cause an enormous "tail" to form pointing away from the Sun.[38]

The coma is generally made of H2O and dust, with water making up to 90% of the volatiles that outflow from the nucleus when the comet is within 3 to 4 astronomical units (450,000,000 to 600,000,000 km; 280,000,000 to 370,000,000 mi) of the Sun.[39] The H2O parent molecule is destroyed primarily through photodissociation and to a much smaller extent photoionization, with the solar wind playing a minor role in the destruction of water compared to photochemistry.[39] Larger dust particles are left along the comet's orbital path whereas smaller particles are pushed away from the Sun into the comet's tail by light pressure.[40]

Although the solid nucleus of comets is generally less than 60 kilometres (37 mi) across, the coma may be thousands or millions of kilometres across, sometimes becoming larger than the Sun.[41] For example, about a month after an outburst in October 2007, comet 17P/Holmes briefly had a tenuous dust atmosphere larger than the Sun.[42] The Great Comet of 1811 also had a coma roughly the diameter of the Sun.[43] Even though the coma can become quite large, its size can actually decrease about the time it crosses the orbit of Mars around 1.5 astronomical units (220,000,000 km; 140,000,000 mi) from the Sun.[43] At this distance the solar wind becomes strong enough to blow the gas and dust away from the coma, enlarging the tail.[43] Ion tails have been observed to extend one astronomical unit (150 million km) or more.[42]

Both the coma and tail are illuminated by the Sun and may become visible when a comet passes through the inner Solar System, the dust reflecting Sunlight directly and the gases glowing from ionisation.[44] Most comets are too faint to be visible without the aid of a telescope, but a few each decade become bright enough to be visible to the naked eye.[45] Occasionally a comet may experience a huge and sudden outburst of gas and dust, during which the size of the coma greatly increases for a period of time. This happened in 2007 to Comet Holmes.[42]

In 1996, comets were found to emit X-rays.[46] This greatly surprised astronomers because X-ray emission is usually associated with very high-temperature bodies. The X-rays are generated by the interaction between comets and the solar wind: when highly charged solar wind ions fly through a cometary atmosphere, they collide with cometary atoms and molecules, "stealing" one or more electrons from the atom in a process called "charge exchange". This exchange or transfer of an electron to the solar wind ion is followed by its de-excitation into the ground state of the ion, leading to the emission of X-rays and far ultraviolet photons.[47]

Tails


Diagram of a comet showing the dust trail, the dust tail (or antitail) and the ion gas tail, which is formed by the solar wind flow.
Gas and snow jets on Comet Hartley 2

In the outer Solar System, comets remain frozen and inactive and are extremely difficult or impossible to detect from Earth due to their small size. Statistical detections of inactive comet nuclei in the Kuiper belt have been reported from observations by the Hubble Space Telescope[48][49] but these detections have been questioned.[50][51] As a comet approaches the inner Solar System, solar radiation causes the volatile materials within the comet to vaporize and stream out of the nucleus, carrying dust away with them.

The streams of dust and gas each form their own distinct tail, pointing in slightly different directions. The tail of dust is left behind in the comet's orbit in such a manner that it often forms a curved tail called the type II or dust tail.[44] At the same time, the ion or type I tail, made of gases, always points directly away from the Sun because this gas is more strongly affected by the solar wind than is dust, following magnetic field lines rather than an orbital trajectory.[52] On occasions - such as when the Earth passes through a comet's orbital plane, and we see the track of the comet edge-on, a tail pointing in the opposite direction to the ion and dust tails may be seen – the antitail.[53] (The dust tail of the comet prior to its rounding of the Sun is collinear with the dust tail post the rounding).[clarification needed]

The observation of antitails contributed significantly to the discovery of solar wind.[54] The ion tail is formed as a result of the ionisation by solar ultra-violet radiation of particles in the coma. Once the particles have been ionized, they attain a net positive electrical charge, which in turn gives rise to an "induced magnetosphere" around the comet. The comet and its induced magnetic field form an obstacle to outward flowing solar wind particles. Because the relative orbital speed of the comet and the solar wind is supersonic, a bow shock is formed upstream of the comet in the flow direction of the solar wind. In this bow shock, large concentrations of cometary ions (called "pick-up ions") congregate and act to "load" the solar magnetic field with plasma, such that the field lines "drape" around the comet forming the ion tail.[55]

If the ion tail loading is sufficient, then the magnetic field lines are squeezed together to the point where, at some distance along the ion tail, magnetic reconnection occurs. This leads to a "tail disconnection event".[55] This has been observed on a number of occasions, one notable event being recorded on April 20, 2007, when the ion tail of Encke's Comet was completely severed while the comet passed through a coronal mass ejection. This event was observed by the STEREO space probe.[56]

In 2013 ESA scientists reported that the ionosphere of the planet Venus streams outwards in a manner similar to the ion tail seen streaming from a comet under similar conditions."[57][58]

Jets

Uneven heating can cause newly generated gases to break out of a weak spot on the surface of comet's nucleus, like a geyser.[59] These streams of gas and dust can cause the nucleus to spin, and even split apart.[59] In 2010 it was revealed dry ice (frozen carbon dioxide) can power jets of material flowing out of a comet nucleus.[60] This is known because a spacecraft got so close that it could see where the jets were coming out, and then measure the infrared spectrum at that point which shows what some of the materials are.[61]

Orbital characteristics

Most comets are small Solar System bodies with elongated elliptical orbits that take them close to the Sun for a part of their orbit and then out into the further reaches of the Solar System for the remainder.[62] Comets are often classified according to the length of their orbital periods: The longer the period the more elongated the ellipse.

Short period

Periodic comets or short-period comets are generally defined as having orbital periods of less than 200 years.[63] They usually orbit more-or-less in the ecliptic plane in the same direction as the planets.[64] Their orbits typically take them out to the region of the outer planets (Jupiter and beyond) at aphelion; for example, the aphelion of Halley's Comet is a little beyond the orbit of Neptune. Comets whose aphelia are near a major planet's orbit are called its "family".[65] Such families are thought to arise from the planet capturing formerly long-period comets into shorter orbits.[66]

At the shorter extreme, Encke's Comet has an orbit that does not reach the orbit of Jupiter, and is known as an Encke-type comet. Short-period comets with orbital periods shorter than 20 years and low inclinations (up to 30 degrees) are called "Jupiter-family comets".[67][68] Those like Halley, with orbital periods of between 20 and 200 years and inclinations extending from zero to more than 90 degrees, are called "Halley-type comets".[69][70] As of 2014, only 74 Halley-type comets have been observed, compared with 492 identified Jupiter-family comets.[71]

Recently discovered main-belt comets form a distinct class, orbiting in more circular orbits within the asteroid belt.[72]

Because their elliptical orbits frequently take them close to the giant planets, comets are subject to further gravitational perturbations.[73] Short-period comets have a tendency for their aphelia to coincide with a giant planet's semi-major axis, with the Jupiter-family comets being the largest group.[68] It is clear that comets coming in from the Oort cloud often have their orbits strongly influenced by the gravity of giant planets as a result of a close encounter. Jupiter is the source of the greatest perturbations, being more than twice as massive as all the other planets combined. These perturbations can deflect long-period comets into shorter orbital periods.[74][75]

Based on their orbital characteristics, short-period comets are thought to originate from the centaurs and the Kuiper belt/scattered disc[76] —a disk of objects in the trans-Neptunian region—whereas the source of long-period comets is thought to be the far more distant spherical Oort cloud (after the Dutch astronomer Jan Hendrik Oort who hypothesised its existence).[77] Vast swarms of comet-like bodies are believed to orbit the Sun in these distant regions in roughly circular orbits. Occasionally the gravitational influence of the outer planets (in the case of Kuiper belt objects) or nearby stars (in the case of Oort cloud objects) may throw one of these bodies into an elliptical orbit that takes it inwards toward the Sun to form a visible comet. Unlike the return of periodic comets, whose orbits have been established by previous observations, the appearance of new comets by this mechanism is unpredictable.[78]

Long period

Orbits of the Kohoutek Comet (red) and the Earth (blue), illustrating the high eccentricity of its orbit and its rapid motion when close to the Sun
Comets C/2012 F6 (Lemmon) (top) and C/2011 L4 (PANSTARRS) (bottom)

Long-period comets have highly eccentric orbits and periods ranging from 200 years to thousands of years.[79] An eccentricity greater than 1 when near perihelion does not necessarily mean that a comet will leave the Solar System.[80] For example, Comet McNaught had a heliocentric osculating eccentricity of 1.000019 near its perihelion passage epoch in January 2007 but is bound to the Sun with roughly a 92,600-year orbit because the eccentricity drops below 1 as it moves further from the Sun. The future orbit of a long-period comet is properly obtained when the osculating orbit is computed at an epoch after leaving the planetary region and is calculated with respect to the center of mass of the Solar System. By definition long-period comets remain gravitationally bound to the Sun; those comets that are ejected from the Solar System due to close passes by major planets are no longer properly considered as having "periods". The orbits of long-period comets take them far beyond the outer planets at aphelia, and the plane of their orbits need not lie near the ecliptic. Long-period comets such as Comet West and C/1999 F1 can have apoapsis distances of nearly 70,000 AU with orbital periods estimated around 6 million years.

Hyperbolic
comet discoveries
Year #
2014 9
2013 8
2012 10
2011 12
2010 4
2009 8
2008 7
2007 12
Source: JPL, SSD[81]

Single-apparition or non-periodic comets are similar to long-period comets because they also have parabolic or slightly hyperbolic trajectories[79] when near perihelion in the inner Solar System. However, gravitational perturbations from giant planets cause their orbits to change. Single-apparition comets have a hyperbolic or parabolic osculating orbit which allows them to permanently exit the Solar System after a single pass of the Sun.[82] The Sun's Hill sphere has an unstable maximum boundary of 230,000 AU (1.1 parsecs (3.6 light-years)).[83] Only a few hundred comets have been seen to achieve a hyperbolic orbit (e > 1) when near perihelion[84] that using a heliocentric unperturbed two-body best-fit suggests they may escape the Solar System.

No comets with an eccentricity significantly greater than one have been observed,[84] so there are no confirmed observations of comets that are likely to have originated outside the Solar System. Comet C/1980 E1 had an orbital period of roughly 7.1 million years before the 1982 perihelion passage, but a 1980 encounter with Jupiter accelerated the comet giving it the largest eccentricity (1.057) of any known hyperbolic comet.[85] Comets not expected to return to the inner Solar System include C/1980 E1, C/2000 U5, C/2001 Q4 (NEAT), C/2009 R1, C/1956 R1, and C/2007 F1 (LONEOS).

Some authorities use the term "periodic comet" to refer to any comet with a periodic orbit (that is, all short-period comets plus all long-period comets),[86] whereas others use it to mean exclusively short-period comets.[79] Similarly, although the literal meaning of "non-periodic comet" is the same as "single-apparition comet", some use it to mean all comets that are not "periodic" in the second sense (that is, to also include all comets with a period greater than 200 years).

Early observations have revealed a few genuinely hyperbolic (i.e. non-periodic) trajectories, but no more than could be accounted for by perturbations from Jupiter. If comets pervaded interstellar space, they would be moving with velocities of the same order as the relative velocities of stars near the Sun (a few tens of km per second). If such objects entered the Solar System, they would have positive specific orbital energy and would be observed to have genuinely hyperbolic trajectories. A rough calculation shows that there might be four hyperbolic comets per century within Jupiter's orbit, give or take one and perhaps two orders of magnitude.[87]

Oort cloud and Hills cloud


The Oort cloud thought to surround the Solar System

The Oort cloud is thought to occupy a vast space from somewhere between 2,000 and 5,000 AU (0.03 and 0.08 ly)[88] to as far as 50,000 AU (0.79 ly)[69] from the Sun. Some estimates place the outer edge at between 100,000 and 200,000 AU (1.58 and 3.16 ly).[88] The region can be subdivided into a spherical outer Oort cloud of 20,000–50,000 AU (0.32–0.79 ly), and a doughnut-shaped inner Oort cloud of 2,000–20,000 AU (0.03–0.32 ly). The outer cloud is only weakly bound to the Sun and supplies the long-period (and possibly Halley-type) comets to inside the orbit of Neptune.[69] The inner Oort cloud is also known as the Hills cloud, named after J. G. Hills, who proposed its existence in 1981.[89] Models predict that the inner cloud should have tens or hundreds of times as many cometary nuclei as the outer halo;[89][90][91] it is seen as a possible source of new comets to resupply the relatively tenuous outer cloud as the latter's numbers are gradually depleted. The Hills cloud explains the continued existence of the Oort cloud after billions of years.[92]

Exocomets

Exocomets beyond our Solar System have also been detected and may be common in the Milky Way Galaxy.[93] The first exocomet system detected was around Beta Pictoris, a very young type A V star, in 1987.[94][95] A total of 10 such exocomet systems have been identified as of 2013, using the absorption spectrum caused by the large clouds of gas emitted by comets when passing close to their star.[93][94]

Effects of comets

Connection to meteor showers


Diagram of Perseids meteors

As a result of outgassing, comets leave in their wake a trail of solid debris too large to be swept away by radiation pressure and the solar wind.[96] If the comet's path crosses the path the Earth follows in orbit around the Sun, then at that point there are likely to be meteor showers as Earth passes through the trail of debris. The Perseid meteor shower, for example, occurs every year between August 9 and August 13, when Earth passes through the orbit of Comet Swift–Tuttle.[97] Halley's Comet is the source of the Orionid shower in October.[97]

Comets and impact on life

Many comets and asteroids collided into Earth in its early stages. Many scientists believe that comets bombarding the young Earth about 4 billion years ago brought the vast quantities of water that now fill the Earth's oceans, or at least a significant portion of it. Other researchers have cast doubt on this theory.[98] The detection of organic molecules, including polycyclic aromatic hydrocarbons,[15] in significant quantities in comets has led some to speculate that comets or meteorites may have brought the precursors of life—or even life itself—to Earth.[99] In 2013 it was suggested that impacts between rocky and icy surfaces, such as comets, had the potential to create the amino acids that make up proteins through shock synthesis.[100]

It is suspected that comet impacts have, over long timescales, also delivered significant quantities of water to the Earth's Moon, some of which may have survived as lunar ice.[101] Comet and meteoroid impacts are also believed responsible for the existence of tektites and australites.[102]

Fate of comets

Departure (ejection) from Solar System

If a comet is traveling fast enough, it may leave the Solar System; such is the case for hyperbolic comets. To date, comets are only known to be ejected by interacting with another object in the Solar System, such as Jupiter.[103] An example of this is thought to be Comet C/1980 E1, which was shifted from a predicted orbit of 7.1 million years around the Sun, to a hyperbolic trajectory, after a 1980 encounter with the planet Jupiter.[104]

Volatiles exhausted

Jupiter-family comets and long-period comets appear to follow very different fading laws. The JFCs are active over a lifetime of about 10,000 years or ~1,000 orbits whereas long-period comets fade much faster. Only 10% of the long-period comets survive more than 50 passages to small perihelion and only 1% of them survive more than 2,000 passages.[29] Eventually most of the volatile material contained in a comet nucleus evaporates away, and the comet becomes a small, dark, inert lump of rock or rubble that can resemble an asteroid.[105] Some asteroids in elliptical orbits are now identified as extinct comets.[106] Roughly six percent of the near-Earth asteroids are thought to be extinct nuclei of comets that no longer emit gas.[29]

Breakup and collisions

The nucleus of some comets may be fragile, a conclusion supported by the observation of comets splitting apart.[107] A significant cometary disruption was that of Comet Shoemaker–Levy 9, which was discovered in 1993. A close encounter in July 1992 had broken it into pieces, and over a period of six days in July 1994, these pieces fell into Jupiter's atmosphere—the first time astronomers had observed a collision between two objects in the Solar System.[108][109] Other splitting comets include 3D/Biela in 1846 and 73P/Schwassmann–Wachmann from 1995 to 2006.[110] Greek historian Ephorus reported that a comet split apart as far back as the winter of 372–373 BC.[111] Comets are suspected of splitting due to thermal stress, internal gas pressure, or impact.[112]

Comets 42P/Neujmin and 53P/Van Biesbroeck appear to be fragments of a parent comet. Numerical integrations have shown that both comets had a rather close approach to Jupiter in January 1850, and that, before 1850, the two orbits were nearly identical.[113]

Some comets have been observed to break up during their perihelion passage, including great comets West and Ikeya–Seki. Biela's Comet was one significant example, when it broke into two pieces during its passage through the perihelion in 1846. These two comets were seen separately in 1852, but never again afterward. Instead, spectacular meteor showers were seen in 1872 and 1885 when the comet should have been visible. A lesser meteor shower, the Andromedids, occurs annually in November, and it is caused when the Earth crosses the orbit of Biela's Comet.[114]

Some comets meet a more spectacular end – either falling into the Sun[115] or smashing into a planet or other body. Collisions between comets and planets or moons were common in the early Solar System: some of the many craters on the Moon, for example, may have been caused by comets. A recent collision of a comet with a planet occurred in July 1994 when Comet Shoemaker–Levy 9 broke up into pieces and collided with Jupiter.[116]
Brown spots mark impact sites
 f Comet Shoemaker–Levy on
Jupiter
Breaking up of 73P/Schwassmann–Wachmann within three days (1995)
Disintegration of P/2013 R3 (HST, 2014).[117]

Nomenclature

Halley's Comet (photo,1910)

The names given to comets have followed several different conventions over the past two centuries. Prior to the early 20th century, most comets were simply referred to by the year when they appeared, sometimes with additional adjectives for particularly bright comets; thus, the "Great Comet of 1680", the "Great Comet of 1882", and the "Great January comet of 1910".

After Edmund Halley demonstrated that the comets of 1531, 1607, and 1682 were the same body and successfully predicted its return in 1759 by calculating its orbit, that comet became known as Halley's Comet.[118] Similarly, the second and third known periodic comets, Encke's Comet[119] and Biela's Comet,[120] were named after the astronomers who calculated their orbits rather than their original discoverers. Later, periodic comets were usually named after their discoverers, but comets that had appeared only once continued to be referred to by the year of their apparition.[121]

In the early 20th century, the convention of naming comets after their discoverers became common, and this remains so today. A comet can be named after its discoverers, or an instrument or program that helped to find it.[121]

History of study

Early observations and thought

Halley's Comet appeared at the Battle of Hastings in 1066 (Bayeux Tapestry).
The orbit of the comet of 1680, fitted to a parabola, as shown in Isaac Newton's Principia

From ancient sources, such as Chinese oracle bones, it is known that their appearances have been noticed by humans for millennia.[122] Until the sixteenth century, comets were usually considered bad omens of deaths of kings or noble men, or coming catastrophes, or even interpreted as attacks by heavenly beings against terrestrial inhabitants.[123][124]

Aristotle believed that comets were atmospheric phenomena, due to the fact that they could appear outside of the Zodiac and vary in brightness over the course of a few days.[125] Pliny the Elder believed that comets were connected with political unrest and death.[126]

In the 16th century Tycho Brahe demonstrated that comets must exist outside the Earth's atmosphere by measuring the parallax of the Great Comet of 1577 from observations collected by geographically separated observers. Within the precision of the measurements, this implied the comet must be at least four times more distant than from the Earth to the Moon.[127][128]

Orbital studies

Isaac Newton, in his Principia Mathematica of 1687, proved that an object moving under the influence of his inverse square law of universal gravitation must trace out an orbit shaped like one of the conic sections, and he demonstrated how to fit a comet's path through the sky to a parabolic orbit, using the comet of 1680 as an example.[129]
In 1705, Edmond Halley (1656–1742) applied Newton's method to twenty-three cometary apparitions that had occurred between 1337 and 1698. He noted that three of these, the comets of 1531, 1607, and 1682, had very similar orbital elements, and he was further able to account for the slight differences in their orbits in terms of gravitational perturbation by Jupiter and Saturn. Confident that these three apparitions had been three appearances of the same comet, he predicted that it would appear again in 1758–9.[130] Halley's predicted return date was later refined by a team of three French mathematicians: Alexis Clairaut, Joseph Lalande, and Nicole-Reine Lepaute, who predicted the date of the comet's 1759 perihelion to within one month's accuracy.[131] When the comet returned as predicted, it became known as Halley's Comet (with the latter-day designation of 1P/Halley). It will next appear in 2061.[132]

Studies of physical characteristics


Isaac Newton described comets as compact and durable solid bodies moving in oblique orbit and their tails as thin streams of vapor emitted by their nuclei, ignited or heated by the Sun.
Newton suspected that comets were the origin of the life-supporting component of air.[134]
As early as the 18th century, some scientists had made correct hypotheses as to comets' physical composition. In 1755, Immanuel Kant hypothesized that comets are composed of some volatile substance, whose vaporization gives rise to their brilliant displays near perihelion.[135] In 1836, the German mathematician Friedrich Wilhelm Bessel, after observing streams of vapor during the appearance of Halley's Comet in 1835, proposed that the jet forces of evaporating material could be great enough to significantly alter a comet's orbit, and he argued that the non-gravitational movements of Encke's Comet resulted from this phenomenon.[136]

In 1950, Fred Lawrence Whipple proposed that rather than being rocky objects containing some ice, comets were icy objects containing some dust and rock.[137] This "dirty snowball" model soon became accepted and appeared to be supported by the observations of an armada of spacecraft (including the European Space Agency's Giotto probe and the Soviet Union's Vega 1 and Vega 2) that flew through the coma of Halley's Comet in 1986, photographed the nucleus, and observed jets of evaporating material.[138]

On 22 January 2014, ESA scientists reported the detection, for the first definitive time, of water vapor on the dwarf planet Ceres, the largest object in the asteroid belt.[139] The detection was made by using the far-infrared abilities of the Herschel Space Observatory.[140] The finding is unexpected because comets, not asteroids, are typically considered to "sprout jets and plumes". According to one of the scientists, "The lines are becoming more and more blurred between comets and asteroids."[140] On 11 August 2014, astronomers released studies, using the Atacama Large Millimeter/Submillimeter Array (ALMA) for the first time, that detailed the distribution of HCN, HNC, H2CO, and dust inside the comae of comets C/2012 F6 (Lemmon) and C/2012 S1 (ISON).[141][142]

Spacecraft missions

  • Deep Impact. Debate continues about how much ice is in a comet. In 2001, the Deep Space 1 spacecraft obtained high-resolution images of the surface of Comet Borrelly. It was found that the surface of comet Borrelly is hot and dry, with a temperature of between 26 to 71 °C (79 to 160 °F), and extremely dark, suggesting that the ice has been removed by solar heating and maturation, or is hidden by the soot-like material that covers Borrelly's.[143] In July 2005, the Deep Impact probe blasted a crater on Comet Tempel 1 to study its interior. The mission yielded results suggesting that the majority of a comet's water ice is below the surface and that these reservoirs feed the jets of vaporised water that form the coma of Tempel 1.[144] Renamed EPOXI, it made a flyby of Comet Hartley 2 on November 4, 2010.
  • Stardust. Data from the Stardust mission show that materials retrieved from the tail of Wild 2 were crystalline and could only have been "born in fire," at extremely high temperatures of over 1,000 °C (1,830 °F).[145][146] Although comets formed in the outer Solar System, radial mixing of material during the early formation of the Solar System is thought to have redistributed material throughout the proto-planetary disk,[147] so comets also contain crystalline grains that formed in the hot inner Solar System. This is seen in comet spectra as well as in sample return missions. More recent still, the materials retrieved demonstrate that the "comet dust resembles asteroid materials".[148] These new results have forced scientists to rethink the nature of comets and their distinction from asteroids.[149]
  • Rosetta. The Rosetta probe is presently in erratic orbit around Comet Churyumov–Gerasimenko. On November 12, 2014, its lander Philae successfully landed on the comet's surface, the first time a spacecraft has ever landed on such an object in history.[150]

Great comets


Woodcut of the Great Comet of 1577

Approximately once a decade, a comet becomes bright enough to be noticed by a casual observer, leading such comets to be designated as Great Comets.[111] Predicting whether a comet will become a great comet is notoriously difficult, as many factors may cause a comet's brightness to depart drastically from predictions.[151] Broadly speaking, if a comet has a large and active nucleus, will pass close to the Sun, and is not obscured by the Sun as seen from the Earth when at its brightest, it has a chance of becoming a great comet. However, Comet Kohoutek in 1973 fulfilled all the criteria and was expected to become spectacular but failed to do so.[152] Comet West, which appeared three years later, had much lower expectations but became an extremely impressive comet.[153]

The late 20th century saw a lengthy gap without the appearance of any great comets, followed by the arrival of two in quick succession—Comet Hyakutake in 1996, followed by Hale–Bopp, which reached maximum brightness in 1997 having been discovered two years earlier. The first great comet of the 21st century was C/2006 P1 (McNaught), which became visible to naked eye observers in January 2007. It was the brightest in over 40 years.[154]

Sungrazing comets

A sungrazing comet is a comet that passes extremely close to the Sun at perihelion, generally within a few million kilometres.[155] Although small sungrazers can be completely evaporated during such a close approach to the Sun, larger sungrazers can survive many perihelion passages. However, the strong tidal forces they experience often lead to their fragmentation.[156]
About 90% of the sungrazers observed with SOHO are members of the Kreutz group, which all originate from one giant comet that broke up into many smaller comets during its first passage through the inner Solar System.[157] The remainder contains some sporadic sungrazers, but four other related groups of comets have been identified among them: the Kracht, Kracht 2a, Marsden, and Meyer groups. The Marsden and Kracht groups both appear to be related to Comet 96P/Machholz, which is also the parent of two meteor streams, the Quadrantids and the Arietids.[158]

Unusual comets

Of the thousands of known comets, some exhibit unusual properties. Encke's Comet (2P/Encke) orbits from outside the asteroid belt to just inside the orbit of the planet Mercury whereas the Comet 29P/Schwassmann–Wachmann currently travels in a nearly circular orbit entirely between the orbits of Jupiter and Saturn.[159] 2060 Chiron, whose unstable orbit is between Saturn and Uranus, was originally classified as an asteroid until a faint coma was noticed.[160] Similarly, Comet Shoemaker–Levy 2 was originally designated asteroid 1990 UL3.[161]

Centaurs

Centaurs typically behave with characteristics of both asteroids and comets.[162] Centaurs can be classified as comets such as 60558 Echeclus, and 166P/NEAT. 166P/NEAT was discovered while it exhibited a coma, and so is classified as a comet despite its orbit, and 60558 Echeclus was discovered without a coma but later became active,[163] and was then classified as both a comet and an asteroid (174P/Echeclus). One plan for Cassini-Huygens involved sending to a Centaur, but NASA decided to destroy it instead.[164]

Observation

A comet may be discovered photographically using a wide-field telescope or visually with binoculars. However, even without access to optical equipment, it is still possible for the amateur astronomer to discover a sungrazing comet online by downloading images accumulated by some satellite observatories such as SOHO.[25] SOHO's 2000th comet was discovered by Polish amateur astronomer Michał Kusiak on 26 December 2010[165] and both discoverers of Hale-Bopp used amateur equipment (although Hale was not an amateur).

Lost

A number of periodic comets discovered in earlier decades or previous centuries are now lost comets. Their orbits were never known well enough to predict future appearances or the comets have disintegrated. However, occasionally a "new" comet is discovered, and calculation of its orbit shows it to be an old "lost" comet. An example is Comet 11P/Tempel–Swift–LINEAR, discovered in 1869 but unobservable after 1908 because of perturbations by Jupiter. It was not found again until accidentally rediscovered by LINEAR in 2001.[166]

Gallery

Videos
NASA is developing a comet harpoon for returning samples to Earth.
Encke's Comet loses its tail

In popular culture

The depiction of comets in popular culture is firmly rooted in the long Western tradition of seeing comets as harbingers of doom and as omens of world-altering change.[168] Halley's Comet alone has caused a slew of sensationalist publications of all sorts at each of its reappearances. It was especially noted that the birth and death of some notable persons coincided with separate appearances of the comet, such as with writers Mark Twain (who correctly speculated that he'd "go out with the comet" in 1910)[168] and Eudora Welty, to whose life Mary Chapin Carpenter dedicated the song Halley Came to Jackson.[168]
In times past, bright comets often inspired panic and hysteria in the general population, being thought of as bad omens. More recently, during the passage of Halley's Comet in 1910, the Earth passed through the comet's tail, and erroneous newspaper reports inspired a fear that cyanogen in the tail might poison millions,[169] whereas the appearance of Comet Hale–Bopp in 1997 triggered the mass suicide of the Heaven's Gate cult.[170]

In science fiction, the impact of comets has been depicted as a threat overcome by technology and heroism (Deep Impact, 1998 and Armageddon, 1998), or as a trigger of global apocalypse (Lucifer's Hammer, 1979) or of waves of zombies (Night of the Comet, 1984).[168] In Jules Verne's Off on a Comet a group of people are stranded on a comet orbiting the Sun, while a large manned space expedition visits Halley's Comet in Sir Arthur C. Clarke's novel 2061: Odyssey Three.[171]

Java


From Wikipedia, the free encyclopedia

Java
Native name: Jawa-ꦗꦮ
Java Topography.png
Topography of Java
Java Locator.svg
Geography
Location Southeast Asia
Coordinates 7°29′30″S 110°00′16″E / 7.49167°S 110.00444°E / -7.49167; 110.00444Coordinates: 7°29′30″S 110°00′16″E / 7.49167°S 110.00444°E / -7.49167; 110.00444
Archipelago Greater Sunda Islands
Area 138,794 km2 (53,589 sq mi)
Area rank 13th
Highest elevation 3,676 m (12,060 ft)
Highest point Semeru
Country
Provinces Banten,
Special Capital Region of Jakarta,
West Java,
Central Java,
East Java,
Yogyakarta Special Region
Largest settlement Jakarta
Demographics
Population 143 million (as of 2014)
Density 1,117 /km2 (2,893 /sq mi)
Ethnic groups Javanese (inc. Cirebonese, Tenggerese, Osing, Banyumasan), Sundanese (inc. Bantenese, Baduy), Betawi, Madurese

Java (Indonesian: Jawa; Javanese: ꦗꦮ) is an island of Indonesia. With a population of 143 million, Java is the World's most populous island, and one of the most densely populated places in the World. Java is the home of 57 percent of the Indonesian population. The Indonesian capital city, Jakarta, is located on western Java. Much of Indonesian history took place on Java. It was the center of powerful Hindu-Buddhist empires, the Islamic sultanates, and the core of the colonial Dutch East Indies. Java was also the center of the Indonesian struggle for independence during the 1930s and 1940s. Java dominates Indonesia politically, economically and culturally.

Formed mostly as the result of volcanic eruptions, Java is the 13th largest island in the World and the fifth largest island in Indonesia. A chain of volcanic mountains forms an east–west spine along the island. It has three main languages, with Javanese being the dominant language; it is the native language of about 60 million people in Indonesia, most of whom live on Java. Most of its residents are bilingual, with Indonesian as their first or second language. While the majority of the people of Java are Muslim, Java has a diverse mixture of religious beliefs, ethnicities, and cultures.

Java is divided into four provinces, West Java, Central Java, East Java, and Banten, and also two special regions, Jakarta and Yogyakarta.

Etymology

The origins of the name "Java" are not clear. One possibility is that the island was named after the jáwa-wut plant, which was said to be common in the island during the time, and that prior to Indianization the island had different names.[1] There are other possible sources: the word jaú and its variations mean "beyond" or "distant".[2] And, in Sanskrit yava means barley, a plant for which the island was famous.[2] "Yawadvipa" is mentioned in India's earliest epic, the Ramayana. Sugriva, the chief of Rama's army dispatched his men to Yawadvipa, the island of Java, in search of Sita.[3] It was hence referred to in Indian by the Sanskrit name "yāvaka dvīpa" (dvīpa = island). Java is mentioned in the ancient Tamil text Manimekalai that states that Java had a kingdom with a capital called Nagapuram.[4][5][6] Another source states that the "Java" word is derived from a Proto-Austronesian root word, meaning 'home'.[7]

Geography


Java lies between Sumatra to the west and Bali to the east. Borneo lies to the north and Christmas Island is to the south. It is the World's 13th largest island. Java is surrounded by Java Sea in the north, Sunda Strait in the west, Indian Ocean in the south and Bali Strait and Madura Strait in the east.
Java is almost entirely of volcanic origin; it contains thirty-eight mountains forming an east–west spine that have at one time or another been active volcanoes. The highest volcano in Java is Mount Semeru (3,676 m). The most active volcano in Java and also in Indonesia is Mount Merapi (2,930 m). See Volcanoes of Java.

More mountains and highlands help to split the interior into a series of relatively isolated regions suitable for wet-rice cultivation; the rice lands of Java are among the richest in the World.[8] Java was the first place where Indonesian coffee was grown, starting in 1699. Today, Coffea arabica is grown on the Ijen Plateau by small-holders and larger plantations.

Parahyangan highland near Buitenzorg, c. 1865–1872

The area of Java is approximately 150,000 km2.[9] It is about 1,000 km (620 mi) long and up to 210 km (130 mi) wide. The island's longest river is the 600 km long Solo River.[10] The river rises from its source in central Java at the Lawu volcano, then flows north and eastward to its mouth in the Java Sea near the city of Surabaya. Other major rivers are Brantas, Citarum, Cimanuk and Serayu.

The average temperature ranges from 22 °C to 29 °C; average humidity is 75%. The northern coastal plains are normally hotter, averaging 34 °C during the day in the dry season. The south coast is generally cooler than the north, and highland areas inland are even cooler.[11] The wet season begins in October and ends in April during that rain falls mostly in the afternoons and intermittently during other parts of the year. The wettest months are January and February.

West Java is wetter than East Java and mountainous regions receive much higher rainfall. The Parahyangan highlands of West Java receive over 4,000 mm annually, while the north coast of East Java receives 900 mm annually.

Natural environment


Male Javan rhino shot in 1934 in West Java. Today only small numbers of Javan rhino survive in Ujung Kulon; it is the World's rarest rhino.

The natural environment of Java is tropical rainforest, with ecosystems ranging from coastal mangrove forests on the north coast, rocky coastal cliffs on the southern coast, and low-lying tropical forests to high altitude rainforests on the slopes of mountainous volcanic regions in the interior. The Javan environment and climate gradually alters from west to east; from wet and humid dense rainforest in western parts, to a dry savanna environment in the east, corresponding to the climate and rainfall in these regions.

Originally Javan wildlife supported a rich biodiversity, where numbers of endemic species of flora and fauna flourished; such as the Javan rhinoceros,[12] Javan banteng, Javan warty pig, Javan hawk-eagle, Javan peafowl, Javan silvery gibbon, Javan lutung, Java mouse-deer, Javan rusa, and Javan leopard. With over 450 species of birds and 37 endemic species, Java is a birdwatcher's paradise.[13] There are about 130 freshwater fish species in Java.[14]

However, Java is also home to large numbers of humans. With an estimated population of 114,733,500 in 1995, Java contains well over half of Indonesia's population.[15] Since ancient times, people have opened the rainforest, altered the ecosystem, shaped the landscapes and created rice paddy and terraces to support the growing population. Javan rice terraces have existed for more than a millennium, and had supported ancient agricultural kingdoms. The growing human population has put severe pressure on Java's wildlife, as rainforests were diminished and confined to highland slopes or isolated peninsulas. Some of Java's endemic species are now critically endangered, with some already extinct; Java used to have Javan tigers and Javan elephants, but both have been rendered extinct. Today, several national parks exist in Java that protect the remnants of its fragile wildlife, such as Ujung Kulon, Mount Halimun-Salak, Gede Pangrango, Baluran, Meru Betiri and Alas Purwo.

Administrative division

The island is administratively divided into four provinces:
and two special regions:

History


Mount Merbabu surrounded by rice fields. Java's volcanic topography and rich agricultural lands are the fundamental factors in its history.

Fossilised remains of Homo erectus, popularly known as the "Java Man", dating back 1.7 million years were found along the banks of the Bengawan Solo River.[16]

The island's exceptional fertility and rainfall allowed the development of wet-field rice cultivation, which required sophisticated levels of cooperation between villages. Out of these village alliances, small kingdoms developed. The chain of volcanic mountains and associated highlands running the length of Java kept its interior regions and peoples separate and relatively isolated.[17] Before the advent of Islamic states and European colonialism, the rivers provided the main means of communication, although Java's many rivers are mostly short. Only the Brantas and Sala rivers could provide long-distance communication, and this way their valleys supported the centres of major kingdoms. A system of roads, permanent bridges and toll gates is thought to have been established in Java by at least the mid-17th century. Local powers could disrupt the routes as could the wet season and road use was highly dependent on constant maintenance. Subsequently, communication between Java's population was difficult.[18]

Hindu-Buddhist kingdoms era

The Taruma and Sunda kingdoms of western Java appeared in the 4th and 7th centuries respectively. However, the first major principality was the Medang Kingdom that was founded in central Java at the beginning of the 8th century. Medang's religion centred on the Hindu god Shiva, and the kingdom produced some of Java's earliest Hindu temples on the Dieng Plateau. Around the 8th century the Sailendra dynasty rose in Kedu Plain and become the patron of Mahayana Buddhism. This ancient kingdom built monuments such as the 9th century Borobudur and Prambanan in central Java.

Prambanan Hindu temple

The 9th century Borobudur Buddhist stupa in Central Java

Around the 10th century the centre of power shifted from central to eastern Java. The eastern Javanese kingdoms of Kediri, Singhasari and Majapahit were mainly dependent on rice agriculture, yet also pursued trade within the Indonesian archipelago, and with China and India.

Majapahit was established by Wijaya and by the end of the reign of Hayam Wuruk (r. 1350-89) it claimed sovereignty over the entire Indonesian archipelago, although control was likely limited to Java, Bali and Madura. Hayam Wuruk's prime minister, Gajah Mada, led many of the kingdom's territorial conquests. Previous Javanese kingdoms had their power based in agriculture, however, Majapahit took control of ports and shipping lanes and became Java's first commercial empire. With the death of Hayam Wuruk and the coming of Islam to Indonesia, Majapahit went into decline.

Spread of Islam and rise of Islamic sultanates

Islam became the dominant religion in Java at the end of the 16th century. During this era, the Islamic kingdoms of Demak, Cirebon, and Banten were ascendant. The Mataram Sultanate became the dominant power of central and eastern Java at the end of the 16th century. The principalities of Surabaya and Cirebon were eventually subjugated such that only Mataram and Banten were left to face the Dutch in the 17th century.

Colonial periods


Tea plantation in Java during Dutch colonial period, in or before 1926

Java's contact with the European colonial powers began in 1522 with a treaty between the Sunda kingdom and the Portuguese in Malacca. After its failure the Portuguese presence was confined to Malacca, and to the eastern islands. In 1596, a four-ship expedition led by Cornelis de Houtman was the first Dutch contact with Indonesia.[19] By the end of the 18th century the Dutch had extended their influence over the sultanates of the interior (see Dutch East India Company in Indonesia). Internal conflict prevented the Javanese from forming effective alliances against the Dutch. Remnants of the Mataram survived as the Surakarta (Solo) and Yogyakarta principalities. Javanese kings claimed to rule with divine authority and the Dutch helped them to preserve remnants of a Javanese aristocracy by confirming them as regents or district officials within the colonial administration.

Java's major role during the early part of the colonial period was as a producer of rice. In spice producing islands like Banda, rice was regularly imported from Java, to supply the deficiency in means of subsistence.[20]

During Napoleonic wars in Europe, the Netherlands fell under France Republic, and so did its colony in East Indies. During the short-lived Daendels administration (as French proxy rule on Java), the construction of Java Great Post Road was commenced in 1808. The road span from Anyer in Western Java to Panarukan in East Java served as a military supply route to defend Java from incoming British invasion.[21]

In 1811, Java was captured by the British, becoming a possession of the British Empire, and Sir Stamford Raffles was appointed as the island's Governor. In 1814, Java was returned to the Dutch under the terms of the Treaty of Paris.[22]

Japanese prepare to discuss surrender terms with British-allied forces in Java 1945

In 1815, there may have been five million people in Java.[23] In the second half of the 18th century, population spurts began in districts along the north-central coast of Java, and in the 19th century population grew rapidly across the island. Factors for the great population growth include the impact of Dutch colonial rule including the imposed end to civil war in Java, the increase in the area under rice cultivation, and the introduction of food plants such as casava and maize that could sustain populations that could not afford rice.[24] Others attribute the growth to the taxation burdens and increased expansion of employment under the Cultivation System to which couples responded by having more children in the hope of increasing their families' ability to pay tax and buy goods.[25] Cholera claimed 100,000 lives in Java in 1820.[26]

The advent of trucks and railways where there had previously only been buffalo and carts, telegraph systems, and more coordinated distribution systems under the colonial government all contributed to famine elimination in Java, and in turn, population growth. There were no significant famines in Java from the 1840s through to the Japanese occupation in the 1940s.[27] Ethnological factors are also thought to have contributed to the increase in population. In Java, there was no absolute preference for boy babies that was significant in Java where agriculture depends on the labour of both men and women. Furthermore, the age of first marriage dropped during the 19th century thus increasing a woman's child bearing years.[27]

Independence

Indonesian nationalism first took hold in Java in the early 20th century (see Indonesian National Awakening), and the struggle to secure the country's independence following World War II was centered in Java. The abortive coup and the subsequent violent anti-communist purge in 1965/66 largely took place in Java. The island has dominated Indonesian social, political and economic life, which has been the source of resentment of those residents in other islands. In 1998, preceding the fall of Suharto's 32-year presidency, large riots targeted the Chinese Indonesians in another series of pogroms.[28]

Demography

Historical population
Year Pop. ±%
1971 76,086,327 —    
1980 91,269,528 +20.0%
1990 107,581,306 +17.9%
2000 121,352,608 +12.8%
2010 136,610,590 +12.6%
2014 143,173,263 +4.8%
sources:[29][30]

Central Jakarta

With a combined population of 136.5 million in the 2010 census (including Madura's 3.6 million),[31] which is estimated for 2014 at 143.1 million (including 3.7 million for Madura), Java is the most populous island in the World and is home to 57% of Indonesia's population.[31] At nearly 1,100 people per km² in 2014, it is also one of the most densely populated parts of the World on par with Bangladesh. Every region of the island has numerous volcanoes, with the people left to share the remaining flatter land. Because of this, many coasts are heavily populated and cities ring around the valleys surrounding volcanic peaks. Thus the physiological density of Java is exceptionally high, even by Asian standards.

Though little population growth is registered in Central Java, East Java, and Yogyakarta, these regions have higher birth rates than one would assume due to mass emigration to the Western side of Java, Sumatra, Borneo, and Papua. Approximately 45% of the population of Indonesia is ethnically Javanese,[32] while Sundanese make a large portion of Java's population as well.

The dense Western third of the island (West Java, Banten, and DKI Jakarta) has an even higher population density of nearly 1,500 per km2 and is taking up the lion's share of the population growth of Java.[31] It is home to three metropolitan areas, Greater Jakarta (with outlying areas of Greater Serang and Greater Sukabumi), Greater Bandung, and Greater Cirebon.

Province or Special Region Capital Area
km²2
Area
%
Population
Census of 2000[33]
Population
Census of 2010[33]
Population
2014 Estimate (Min. Health)[30]
Population
Density in 2014
Banten Serang 9,662.92 7.1 8,098,277 10,632,166 11,834,087 1,224
DKI Jakarta - 664.01 0.5 8,361,079 9,607,787 10,135,030 15,263
West Java Bandung 35,377.76 27.1 35,724,093 43,053,732 46,300,543 1,309
Central Java Semarang 32,800.69 25.3 31,223,258 32,382,657 32,779,832 999
Yogyakarta Yogyakarta 3,133.15 2.4 3,121,045 3,457,491 3,594,290 1,147
East Java Surabaya 47,799.75 37.3 34,765,993 37,476,757 38,529,481 806
Region Administered as Java Jakarta 129,438.28 100% 121,293,745 136,610,590 143,173,263 1,106
Madura Island of East Java
- 5,025.30 3.3 3,230,300 3,622,763 3,724,545 741
Java Island1)
- 124,412.98 96.7 118,063,445 132,987,827 139,448,718 1,121
1) Other islands are included in this figure, but are very small in population and area, Nusa Barung 100 km2, Bawean 196 km2, Karimunjawa 78 km2, Kambangan 121 km2, Panaitan 170 km2, Thousand Islands 8.7 km2 - with a combined population of roughly 90,000.
2) Land area of provinces updated in 2010 Census figures, areas may be different than past results.

From the 1970s to the fall of the Suharto regime in 1998, the Indonesian government ran transmigration programs aimed at resettling the population of Java on other less-populated islands of Indonesia. This program has met with mixed results; sometimes causing conflicts between the locals and the recently arrived settlers. However, Java's share of the nation's population has fallen steadily.

Jakarta and its outskirts being the dominant metropolis is also home to people from all over the nation. East Java is also home to ethnic Balinese, as well as large numbers of Madurans due to their historic poverty.

Ethnicity and culture


A teenager in Java wearing traditional Javanese attire: blangkon headgear, batik sarong and kris as accessory. 1913

Despite its large population and in contrast to the other larger islands of Indonesia, Java is comparatively homogeneous in ethnic composition. Only two ethnic groups are native to the island—the Javanese and Sundanese. A third group is the Madurese, who inhabit the island of Madura off the north east coast of Java, and have immigrated to East Java in large numbers since the 18th century.[34] The Javanese comprise about two-thirds of the island's population, while the Sundanese and Madurese account for 20% and 10% respectively.[34] The fourth group is the Betawi people that speak a dialect of Malay, they are the descendants of the people living around Batavia from around the 17th century. Betawis are creole people, mostly descended from various Indonesian archipelago ethnic groups such as Malay, Sundanese, Javanese, Balinese, Minang, Bugis, Makassar, Ambonese, mixed with foreign ethnic groups such as Portuguese, Dutch, Arab, Chinese and Indian brought to or attracted to Batavia to meet labour needs. They have a culture and language distinct from the surrounding Sundanese and Javanese.

The Javanese kakawin Tantu Pagelaran explained the mythical origin of the island and its volcanic nature. Four major cultural areas exist on the island: the kejawen or Javanese heartland, the north coast of the pasisir region, the Sunda lands of West Java, and the eastern salient, also known as Blambangan. Madura makes up a fifth area having close cultural ties with coastal Java.[34] The kejawen Javanese culture is the island's most dominant. Java's remaining aristocracy are based here, and it is the region from where the majority of Indonesia's army, business, and political elite originate. Its language, arts, and etiquette are regarded as the island's most refined and exemplary.[34] The territory from Banyumas in the west through to Blitar in the east and encompasses Indonesia's most fertile and densely populated agricultural land.[34]

In the southwestern part of Central Java, which is usually named the Banyumasan region, a cultural mingling occurred; bringing together Javanese culture and Sundanese culture to create the Banyumasan culture.[citation needed] In the central Javanese court cities of Yogyakarta and Surakarta, contemporary kings trace their lineages back to the pre-colonial Islamic kingdoms that ruled the region, making those places especially strong repositories of classical Javanese culture. Classic arts of Java include gamelan music and wayang puppet shows.

Java was the site of many influential kingdoms in the Southeast Asian region,[35] and as a result, many literary works have been written by Javanese authors. These include Ken Arok and Ken Dedes, the story of the orphan who usurped his king, and married the queen of the ancient Javanese kingdom; and translations of Ramayana and Mahabharata. Pramoedya Ananta Toer is a famous contemporary Indonesian author, who has written many stories based on his own experiences of having grown up in Java, and takes many elements from Javanese folklore and historical legends.

Languages


Languages spoken in Java (Javanese is shown in white). "Malay" refers to Betawi, the local dialect as one of Malay creole dialect.

The three major languages spoken on Java are Javanese, Sundanese and Madurese. Other languages spoken include Betawi (a Malay dialect local to the Jakarta region), Osing, Banyumasan, and Tenggerese (closely related to Javanese), Baduy (closely related to Sundanese), Kangeanese (closely related to Madurese), and Balinese.[36] The vast majority of the population also speaks Indonesian, often as a second language.

Religion


Mosque in Pati, Central Java during colonial period. The mosque combined traditional Javanese style (multi-tiered roof) with European architecture.

Java has been a melting pot of religions and cultures, which has created a broad range of religious belief.

Indian influences came first with Shaivism and Buddhism penetrating deeply into society, blending with indigenous tradition and culture.[37] One conduit for this were the ascetics, called resi, who taught mystical practices. A resi lived surrounded by students, who took care of their master's daily needs. Resi's authorities were merely ceremonial. At the courts, Brahmin clerics and pudjangga (sacred literati) legitimised rulers and linked Hindu cosmology to their political needs.[37] Small Hindu enclaves are scattered throughout Java, but there is a large Hindu population along the eastern coast nearest Bali, especially around the town of Banyuwangi.

Islam, which came after Hinduism, strengthened the status structure of this traditional religious pattern. More than 90 percent of the people of Java are Muslims, on a broad continuum between abangan (more traditional) and santri (more modernist). The Muslim scholar of the writ (Kyai) became the new religious elite as Hindu influences receded. Islam recognises no hierarchy of religious leaders nor a formal priesthood, but the Dutch colonial government established an elaborate rank order for mosque and other Islamic preaching schools. In Javanese pesantren (Islamic schools), The Kyai perpetuated the tradition of the resi. Students around him provided his needs, even peasants around the school.[37]

Pre-Islamic Javan traditions have encouraged Islam in a mystical direction. There emerged in Java a loosely structured society of religious leadership, revolving around kyais, possessing various degrees of proficiency in pre-Islamic and Islamic lore, belief and practice.[37] The kyais are the principal intermediaries between the villages masses and the realm of the supernatural. However, this very looseneess of kyai leadership structure has promoted schism. There were often sharp divisions between orthodox kyais, who merely instructed in Islamic law, with those who taught mysticism and those who sought reformed Islam with modern scientific concepts. As a result, there is a division between santri, who believe that they are more orthodox in their Islamic belief and practice, with abangan, who have mixed pre-Islamic animistic and Hindu-Indian concepts with a superficial acceptance of Islamic belief.[37]

There are also Christian communities, mostly in the larger cities, though some rural areas of south-central Java are strongly Roman Catholic. Buddhist communities also exist in the major cities, primarily among the Chinese Indonesian. The Indonesian constitution recognises six official religions. (See Religion in Indonesia.)

A wider effect of this division is the number of sects. In the middle of 1956, the Department of Religious Affairs in Yogyakarta reported 63 religious sects in Java other than the official Indonesian religions. Of these, 35 were in Central Java, 22 in West Java and six in East Java.[37] These include Kejawen, Sumarah, Subud, etc. Their total membership is difficult to estimate as many of their adherents identify themselves with one of the official religions.[38]

Economy


Javanese women planting rice in a rice field near Prambanan, Yogyakarta

Initially the economy of Java relied heavily on rice agriculture. Ancient kingdoms such as the Tarumanagara, Mataram, and Majapahit were dependent on rice yields and tax. Java was famous for rice surpluses and rice export since ancient times, and rice agriculture contributed to the population growth of the island. Trade with other parts of Asia such as India and China flourished as early as the 4th century, as evidenced by Chinese ceramics found on the island dated to that period. Java also took part in the global trade of Maluku spice from ancient times in the Majapahit era, until well into the VOC era.

Dutch East India Company set their foothold on Batavia in the 17th century and was succeeded by Netherlands East Indies in the 18th century. During these colonial times, the Dutch introduced the cultivation of commercial plants in Java, such as sugarcane, rubber, coffee, tea, and quinine. In the 19th and early 20th century, Javanese coffee gained global popularity. Thus, the name "Java" today has become a synonym for coffee.

Java transportation network

Java is the most developed island in Indonesia since the era of Netherlands East Indies to modern Republic of Indonesia. The road transportation networks that have existed since ancient times were connected and perfected with the construction of Java Great Post Road by Daendels in the early 19th century. The Java Great Post Road become the backbone of Java's road infrastructure and laid the base of Java North Coast Road (Indonesian: Jalan Pantura, abbreviation from "Pantai Utara"). The need to transport commercial produces such as coffee from plantations in the interior of the island to the harbour on the coast spurred the construction of railway networks in Java. Today the industry, business and trade, also services flourished in major cities of Java, such as Jakarta, Surabaya, Semarang, and Bandung; while some traditional Sultanate cities such as Yogyakarta, Surakarta, and Cirebon preserved its royal legacy and become the centre of art, culture and tourism in Java. Industrial estates also growing in towns on northern coast of Java, especially around Cilegon, Tangerang, Bekasi, Karawang, Gresik and Sidoarjo. The toll road highway networks was built and expanded since Suharto era until now, connecting major urban centres and surrounding areas, such as in and around Jakarta and Bandung; also the ones in Cirebon, Semarang and Surabaya. In addition to these motorways, Java has 16 national highways.

Based on the statistical data by the year of 2012 which's released by Badan Pusat Statistik, Java Island itself contributes at least 57.51% of Indonesia's Gross Domestic Product or equivalent to 504 billions US$.

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