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{{for|the story by Larry Niven|Neutron Star (short story)}}
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[[File:Neutron Star Manhattan.ogv|thumb|300px|Neutron stars contain 500,000 times the mass of the Earth in a sphere with a diameter no larger than that of [[Brooklyn]], [[United States]]]]
[[File:Crash and Burst.ogv|thumb|300px|Video animation of two [[neutron star collision|neutron stars colliding]]]]
 
A '''neutron star''' is a type of [[compact star|stellar remnant]] that can result from the [[gravitational collapse]] of a massive [[star]] during a [[Type II supernova|Type II]], [[Type Ib and Ic supernovae|Type Ib or Type Ic]] [[supernova]] event. Neutron stars are the densest and tiniest stars known to exist in the [[universe]]; although having only the diameter of about 10&nbsp;km (6&nbsp;mi), they may have a mass of several times that of the Sun. Neutron stars probably appear white to the naked eye.
 
Neutron stars are the end points of stars whose mass after [[nuclear fusion|nuclear burning]] is greater than the [[Chandrasekhar limit]] for [[white dwarf]]s, but whose mass is not great enough to overcome the [[degenerate matter#Neutron degeneracy|neutron degeneracy pressure]] to become [[black hole]]s. Such stars are composed almost entirely of [[neutron]]s, which are subatomic particles without net [[electrical charge]] and with slightly larger mass than [[proton]]s. Neutron stars are very hot and are supported against further collapse by [[Degenerate matter|quantum degeneracy pressure]] due to the phenomenon described by the [[Pauli exclusion principle]]. This principle states that no two neutrons (or any other [[fermion]]ic particles) can occupy the same place and [[quantum state]] simultaneously.
 
The discovery of [[pulsar]]s in 1967 suggested that neutron stars exist. Born in supernova explosions, these bodies are "only" ~12-13 kilometers by radius and spin around as rapidly as 642 times a second,<ref name="discovery">{{cite journal | author = Backer, D.; Kulkarni, S.; Heiles, C.; Davis, M.; Goss, M. | title = Millisecond Pulsar in 4C 21.53 | journal = IAU Circ. | volume = 3743 | year = 1982 | editor = B.G. Marsden | bibcode = 1982IAUC.3743....2B | pages = 2 | issue = 2 | last2 = Kulkarni | last3 = Heiles | last4 = Davis | last5 = Goss}}</ref> or approximately 38,500 [[revolutions per minute]]. A typical neutron star has a [[mass]] between ~1.4 and 3.2 [[solar mass]]es with a surface temperature of ~6 x 10<sup>5</sup> Kelvin <ref name=Kiziltan>{{cite book|title=Reassessing the Fundamentals: On the Evolution, Ages and Masses of Neutron Stars|author=Bulent Kiziltan | isbn=1-61233-765-1 |publisher=Universal-Publishers | year=2011}}</ref><ref>{{cite arXiv |eprint=1011.4291 |author1=Bulent Kiziltan |author2=Athanasios Kottas |author3=Stephen E. Thorsett |title=The Neutron Star Mass Distribution |class=astro-ph.GA |year=2010}}</ref><ref>{{cite web | url=http://imagine.gsfc.nasa.gov/docs/ask_astro/answers/010607a.html | title=Nasa Ask an Astrophysist: Maximum Mass of a Neutron Star}}</ref>
(see [[Chandrasekhar limit]]).<ref name=Haensel>{{cite book |title=Neutron Stars |author=Paweł Haensel, A Y Potekhin, D G Yakovlev |isbn=0-387-33543-9 |publisher=Springer |year=2007}}</ref><ref group=lower-alpha>A neutron star's density increases as its mass increases, and its radius decreases non-linearly. ([http://ixo.gsfc.nasa.gov/old_conx_pages/images/science/neutron_stars/ns_mass_radius.gif NASA mass radius graph])</ref>
In contrast, the [[Sun]]'s radius is about 60,000 times that. Neutron stars have overall densities of {{val|3.7|e=17}} to {{val|5.9|e=17|u=kg/m<sup>3</sup>}} ({{val|2.6|e=14}} to {{val|4.1|e=14}} times the density of the Sun),<ref group=lower-alpha>{{val|3.7|e=17|u=kg/m<sup>3</sup>}} derives from mass 2.68{{Esp|30}}&nbsp;kg / volume of star of radius 12&nbsp;km; {{val|5.9|e=17|u=kg m<sup>−3</sup>}} derives from mass {{val|4.2|e=30|u=kg}} per volume of star radius 11.9&nbsp;km</ref> which is comparable to the approximate density of an [[atomic nucleus]] of {{val|3|e=17|u=kg/m<sup>3</sup>}}.<ref>{{cite web| url=http://heasarc.gsfc.nasa.gov/docs/xte/learning_center/ASM/ns.html| title=Calculating a Neutron Star's Density| accessdate=2006-03-11}} NB 3{{Esp|17}}&nbsp;kg/m<sup>3</sup> is {{val|3|e=14|u=g/cm<sup>3</sup>}}</ref>
The neutron star's density varies from below {{val|1|e=9|u=kg/m<sup>3</sup>}} in the crust - increasing with depth - to above {{val|6|e=17}} or {{val|8|e=17|u=kg/m<sup>3</sup>}} deeper inside (denser than an atomic nucleus).<ref name="Miller">{{cite web| url=http://www.astro.umd.edu/~miller/nstar.html| title=Introduction to neutron stars| accessdate=2007-11-11}}</ref> This density is approximately equivalent to the mass of a [[Boeing 747]] compressed to the size of a small grain of sand. A normal-sized matchbox containing neutron star material would have a mass of approximately 5 trillion tonnes.
 
In general, compact stars of less than 1.44&nbsp;solar masses – the [[Chandrasekhar limit]] – are [[white dwarf]]s, and above 2 to 3 solar masses (the [[Tolman–Oppenheimer–Volkoff limit]]), a [[quark star]] might be created; however, this is uncertain. [[Gravitational collapse]] will usually  occur on any [[compact star]] between 10 and 25 solar masses and produce a [[black hole]].<ref name="Black Hole">[http://imagine.gsfc.nasa.gov/docs/science/know_l2/black_holes.html], a ten stellar mass star will collapse into a black hole.</ref> Some neutron stars rotate very rapidly and emit beams of electromagnetic radiation as [[pulsar]]s. [[Gamma-ray burst]]s may be produced from rapidly rotating, high-mass stars that collapse to form a neutron star, or from the merger of binary neutron stars. There are thought to be on the order of 10<sup>8</sup> neutron stars in the galaxy, but they can only be easily detected in certain instances, such as if they are a pulsar or part of a binary system. Non-rotating and non-accreting neutron stars are virtually undetectable; however, the [[Hubble Space Telescope]] has observed one thermally radiating neutron star, called [[RX J1856.5-3754|RX J185635-3754]].
[[File:Neutron star collision.ogv|thumb|Neutron star collision]]
 
==Formation==
Any star with an initial main-sequence mass of around 10 solar masses or above has the potential to become a neutron star. As the star evolves away from the main sequence, subsequent nuclear burning produces an iron-rich core. When all nuclear fuel in the core has been exhausted, the core must be supported by degeneracy pressure alone. Further deposits of material from shell burning cause the core to exceed the Chandrasekhar limit. Electron degeneracy pressure is overcome and the core collapses further, sending temperatures soaring to over 5 billion Kelvin. At these temperatures, [[photodisintegration]] (the breaking up of iron nuclei into alpha particles by high- energy gamma rays) occurs. As the temperature climbs even higher, electrons and protons combine to form neutrons, releasing a flood of neutrinos. When densities reach nuclear density of 4 x 10<sup>17</sup> kilograms per cubic meter, neutron degeneracy pressure halts the contraction. The infalling outer atmosphere of the star is flung outwards, becoming a Type II or Type Ib supernova. The remnant left is a neutron star. If it has a mass greater than about 2-3 solar masses, it collapses further to become a black hole. Other neutron stars are formed within close binaries.
 
As the core of a massive star is compressed during a [[supernova]], and collapses into a neutron star, it retains most of its [[angular momentum]]. Since it has only a tiny fraction of its parent's radius (and therefore its [[moment of inertia]] is sharply reduced), a neutron star is formed with very high rotation speed, and then gradually slows down. Neutron stars are known to have rotation periods from about 1.4 ms to 30 seconds. The neutron star's density also gives it very high [[surface gravity]], up to 7{{e|12}} m/s<sup>2</sup> with typical values of a few {{e|12}} m/s<sup>2</sup> (that is more than 10<sup>11</sup> times of that of [[Earth]]). One measure of such immense gravity is the fact that neutron stars have an [[escape velocity]] of around [[Orders of magnitude (speed)#8|100,000 km/s]], about a third of the [[speed of light]]. Matter falling onto the surface of a neutron star would be accelerated to tremendous speed by the star's gravity. The force of impact would likely destroy the object's component atoms, rendering all its matter identical, in most respects, to the rest of the star.{{Citation needed|date=April 2011}}
 
==Properties==
[[File:Neutronstar 2Rs.svg|thumb|right|Gravitational light deflection at a neutron star. Due to relativistic light deflection more than half of the surface is visible (each chequered patch here represents 30 degrees by 30 degrees).<ref name="Zahn"/> In [[Geometrized unit system|natural units]], the mass of the depicted star is 1 and its radius 4, or twice its [[Schwarzschild radius]].<ref name="Zahn"/>]]
 
The surface of the neutron star is made of iron. In the presence of a strong magnetic field the atoms of iron polymerize. The polymers pack to form a lattice with density about ten thousand times that of terrestrial iron and strength a million times that of steel. It has excellent electrical conductivity along the direction of the magnetic field, but is a good insulator perpendicular to this direction. Immediately beneath this surface the neutron star is still solid, but its composition is changing. Larger nuclei, particularly rich in neutrons, are formed, and materials that on Earth would be radioactive are stable in this environment, such as nickel-62. With increasing depth, the density rises. When its density reaches 400 billion times that of water, the nuclei can get no larger and neutrons start ‘dripping’ out. As the density goes up further, the nuclei dissolve in a sea of neutrons. The neutron fluid is a superfluid – it has no viscosity and no resistance to flow or movement. Within a few kilometres of the surface the density has reached the density of the atomic nucleus. Up to this point the properties of matter are reasonably well understood, but beyond it understanding becomes increasingly sketchy. The composition of the core of the star is particularly uncertain: it may be liquid or solid; it may consist of other nuclear particles (pions, for example, or hyperons); and there may be another phase change, where quarks start ‘dripping’ out of the neutrons, forming another liquid.
 
A neutron star has a mass comparable to that of the Sun, but as it is only about 10&nbsp;km (6&nbsp;mi) in radius, it has an average density 1 quadrillion times that of water. Such a large mass in such a small volume produces an intense gravitational force: objects weigh 100 billion times more on the surface of a neutron star than on the surface of the Earth. The intense gravitational field affects light and other electromagnetic radiation emitted by the star, producing significant redshift (z approximately equal to 0.2). The strong gravitational attraction allows neutron stars to spin rapidly (hundreds of revolutions per second) without disintegrating. Such spin rates are expected if the core of the original star collapses without loss of angular momentum - if the original star has a magnetic field, then this too may be conserved and concentrated in the collapse to a neutron star. Pulsars, gamma-ray burst sources, and the neutron stars in some X-ray binaries are believed to have magnetic fields with a strength of about 100 million Tesla (roughly a million million times the strength of the Earth’s magnetic field).
 
The gravitational field at the star's surface is about 2{{e|11}} times stronger than on Earth.  Such a strong gravitational field acts as a [[gravitational lens]] and bends the radiation emitted by the star such that parts of the normally invisible rear surface become visible.<ref name="Zahn">{{cite web |first=Corvin |last=Zahn |title=Tempolimit Lichtgeschwindigkeit |date=1990-10-09 |url=http://www.tempolimit-lichtgeschwindigkeit.de/galerie/galerie.html |language=German |quote=Durch die gravitative Lichtablenkung ist mehr als die Hälfte der Oberfläche sichtbar. Masse des Neutronensterns: 1, Radius des Neutronensterns: 4, ... dimensionslosen Einheiten (c, G = 1) |accessdate=2009-10-09 }}</ref>
 
A fraction of the mass of a star that collapses to form a neutron star is released in the supernova explosion from which it forms (from the law of mass-energy equivalence, {{nowrap|''E'' {{=}} ''mc''<sup>2</sup>}}). The energy comes from  the [[gravitational binding energy]] of a neutron star.
 
Neutron star relativistic equations of state provided by Jim Lattimer include a graph of radius vs. mass for various models.<ref>[http://www.ns-grb.com/PPT/Lattimer.pdf Neutron Star Masses and Radii], p. 9/20, bottom</ref>  The most likely radii for a given neutron star mass are bracketed by models AP4 (smallest radius) and MS2 (largest radius).  BE is the ratio of gravitational binding energy mass equivalent to observed neutron star gravitational mass of "M" kilograms with radius "R" meters,<ref>[http://iopscience.iop.org/0004-637X/550/1/426/fulltext J. M. Lattimer and M. Prakash], "Neutron Star Structure and the Equation of State" Astrophysical J. 550(1) 426 (2001); http://arxiv.org/abs/astro-ph/0002232</ref>
 
:<math>BE = \frac{0.60\,\beta}{1 - \frac{\beta}{2}}</math>&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;&nbsp;<math>\beta \ = G\,M/R\,{c}^{2}</math>
 
Given current values
 
:<math>G = 6.6742\times10^{-11}\, m^3kg^{-1}sec^{-2}</math><ref>[http://www.npl.washington.edu/eotwash/publications/pdf/prl85-2869.pdf Measurement of Newton's Constant Using a Torsion Balance with Angular Acceleration Feedback ], Phys. Rev. Lett. 85(14) 2869 (2000)</ref>
 
:<math>c^2 = 8.98755\times10^{16}\, m^2sec^{-2}</math>
 
:<math>M_{solar} = 1.98844\times10^{30}\, kg</math>
 
and star masses "M" commonly reported as multiples of one solar mass,
 
:<math>M_x = \frac{M}{M_\odot}</math>
 
then the relativistic fractional binding energy of a neutron star is
 
:<math>BE = \frac{885.975\,M_x}{R - 738.313\,M_x}</math>
 
A two-solar-mass neutron star would not be more compact than 10,970 meters radius (AP4 model).  Its mass fraction gravitational binding energy would then be 0.187, −18.7% (exothermic).  This is not near 0.6/2 = 0.3, −30%.
 
A neutron star is so dense that one teaspoon (5 [[milliliter]]s) of its material would have a mass over {{val|5.5|e=12|u=kg}} (that is 1100 [[tonne]]s per 1 [[Litre#SI prefixes applied to the litre|nanolitre]]), about 900 times the mass of the [[Great Pyramid of Giza]].<ref group=lower-alpha>The average density of material in a neutron star of radius 10 km is {{val|1.1|e=12|u=kg cm<sup>−3</sup>}}. Therefore, 5 ml of such material is {{val|5.5|e=12|u=kg}}, or 5 500 000 000 [[metric ton]]s. This is about 15 times the total mass of the human world population. Alternatively, 5 ml from a neutron star of radius 20&nbsp;km radius (average density {{val|8.35|e=10|u=kg cm<sup>−3</sup>}}) has a mass of about 400 million metric tons, or about the mass of all humans.</ref> Hence, the gravitational force of a typical neutron star is such that if an object were to fall from a height of one meter, it would only take one [[microsecond]] to hit the surface of the neutron star, and would do so at around 2000 kilometers per second, or 7.2 million kilometers per hour.<ref>[http://en.allexperts.com/q/Astronomy-1360/Neutron-Stars-2.htm Miscellaneous Facts]</ref>
 
The temperature inside a newly formed neutron star is from around [[Orders of magnitude (numbers)#1011|10<sup>11</sup>]] to [[10^12|10<sup>12</sup>]] [[kelvin]].<ref name="Miller"/> However, the huge number of [[neutrino]]s it emits carry away so much energy that the temperature falls within a few years to around [[Orders of magnitude (numbers)#106|10<sup>6</sup>]] kelvin.<ref name="Miller"/> Even at 1 million kelvin, most of the light generated by a neutron star is in [[X-ray]]s. In visible light, neutron stars probably radiate approximately the same energy in all parts of visible spectrum, and therefore appear white.
 
The pressure increases from 3×10<sup>33</sup> to 1.6×10<sup>35</sup> Pa from the inner crust to the center.<ref>[http://www.physicsforums.com/archive/index.php/t-209796.html Neutron degeneracy pressure] (Archive). Physics Forums. Retrieved on 2011-10-09.</ref>
 
The [[equation of state]] for a neutron star is still not known.<!-- experts, please update with any news --> It is assumed that it differs significantly from that of a [[white dwarf]], whose EOS is that of a [[degenerate gas]] which can be described in close agreement with [[special relativity]]. However, with a neutron star the increased effects of general relativity can no longer be ignored. Several EOS have been proposed (FPS, UU, APR, L, SLy, and others) and current research is still attempting to constrain the theories to make predictions of neutron star matter.<ref name=Haensel/><ref name="NASAEOS">NASA. [http://ixo.gsfc.nasa.gov/old_conx_pages/science/neutron_star/index.html Neutron Star Equation of State Science] Retrieved 2011-09-26</ref> This means that the relation between density and mass is not fully known, and this causes uncertainties in radius estimates. For example, a 1.5 solar mass neutron star could have a radius of 10.7, 11.1, 12.1 or 15.1 kilometres (for EOS FPS, UU, APR or L respectively).<ref name="NASAEOS"/>
 
==Structure==
[[Image:Neutron star cross section.svg|thumb|500px|right|Cross-section of neutron star. Densities are in terms of ''ρ<sub>0</sub>'' the saturation nuclear matter density, where nucleons begin to touch.]]
 
Current understanding of the structure of neutron stars is defined by existing mathematical models, but it might be possible to infer through studies of [[neutron-star oscillations]]. Similar to [[asteroseismology]] for ordinary stars, the inner structure might be derived by analyzing observed [[Frequency spectrum|frequency spectra]] of stellar oscillations.<ref name=Haensel/>
 
On the basis of current models, the matter at the surface of a neutron star is composed of ordinary [[atomic nucleus|atomic nuclei]] crushed into a solid lattice with a sea of [[electron]]s flowing through the gaps between them. It is possible that the nuclei at the surface are [[iron]], due to iron's high [[binding energy]] per nucleon.<ref name="Surface">V. S. Beskin (1999). "''Radiopulsars''". УФН. T.169, №11, p.1173-1174</ref> It is also possible that heavy element cores, such as iron, simply sink beneath the surface, leaving only light nuclei like [[helium]] and [[hydrogen]] cores.<ref name="Surface"/> If the surface temperature exceeds 10<sup>6</sup> kelvin (as in the case of a young [[pulsar]]), the surface should be fluid instead of the solid phase observed in cooler neutron stars (temperature <10<sup>6</sup> kelvin).<ref name="Surface"/>
 
The "atmosphere" of the star is hypothesized to be at most several micrometers thick, and its dynamic is fully controlled by the star's magnetic field. Below the atmosphere one encounters a solid "crust". This crust is extremely hard and very smooth (with maximum surface irregularities of ~5&nbsp;mm), because of the extreme gravitational field.<ref>[http://www.daviddarling.info/encyclopedia/N/neutronstar.html neutron star<!-- Bot generated title -->]</ref>
 
Proceeding inward, one encounters nuclei with ever increasing numbers of neutrons; such nuclei would decay quickly on Earth, but are kept stable by tremendous pressures. As this process continues at increasing depths, [[neutron drip line|neutron drip]] becomes overwhelming, and the concentration of free neutrons increases rapidly. In this region, there are nuclei, free electrons, and free neutrons. The nuclei become increasingly small (gravity and pressure overwhelming the [[strong force]]) until the core is reached, by definition the point where they disappear altogether.
 
The composition of the superdense matter in the core remains uncertain. One model describes the core as [[superfluid]] [[Degenerate matter#Neutron degeneracy|neutron-degenerate matter]] (mostly neutrons, with some protons and electrons). More exotic forms of matter are possible, including degenerate [[strange matter]] (containing [[strange quark]]s in addition to [[up quark|up]] and [[down quark]]s), matter containing high-energy [[pion]]s and [[kaon]]s in addition to neutrons,<ref name=Haensel /> or ultra-dense [[Degenerate matter#Quark degeneracy|quark-degenerate matter]].
 
==History of discoveries==
[[Image:IsolatedNeutronStar.jpg|thumb|right|200px|The first direct observation of a neutron star in visible light. The neutron star is [[RX J185635-3754]].]]
 
In 1934, [[Walter Baade]] and [[Fritz Zwicky]] proposed the existence of the neutron star,<ref>{{cite journal| journal=Phys. Rev.| volume=46| title=Remarks on Super-Novae and Cosmic Rays| issue=1|author=Baade, Walter and Zwicky, Fritz|pages=76–77|doi=10.1103/PhysRev.46.76.2| year=1934|bibcode = 1934PhRv...46...76B }}</ref>{{refn|group=lower-alpha|Even before the discovery of neutron, in 1931, neutron stars were ''anticipated'' by [[Lev Landau]], who wrote about stars where "atomic nuclei come in close contact, forming one gigantic nucleus"<ref>{{cite journal| journal=Phys. Z. Sowjetunion| volume=1| title=On the theory of stars|author=Landau L.D.| pages=285–288|year=1932}}</ref>). However, the widespread opinion that Landau ''predicted'' neutron stars proves to be wrong.<ref>P. Haensel, A. Y. Potekhin, & D. G. Yakovlev (2007). ''Neutron Stars 1: Equation of State and Structure'' (New York: Springer), page 2 http://adsabs.harvard.edu/abs/2007ASSL..326.....H</ref>}} only a year after [[Neutron#Discovery|the discovery of the neutron]] by Sir [[James Chadwick]].<ref>{{cite journal
| journal=Nature | volume=129
| issue=3252 | pages=312
| title=On the possible existence of a neutron
| first=James | last=Chadwick
| doi=10.1038/129312a0 | year=1932 |bibcode = 1932Natur.129Q.312C }}</ref> In seeking an explanation for the origin of a [[supernova]], they tentatively proposed that in supernova explosions ordinary stars are turned into stars that consist of extremely closely packed neutrons that they called neutron stars. Baade and Zwicky correctly proposed at that time that the release of the gravitational binding energy of the neutron stars powers the supernova: "In the supernova process, mass in bulk is annihilated". Neutron stars were thought to be too faint to be detectable and little work was done on them until November 1967, when Franco Pacini (1939– ) pointed out that if the neutron stars were spinning and had large magnetic fields, then electromagnetic waves would be emitted. Unbeknown to him, radio astronomer Antony Hewish and his research assistant Jocelyn Bell at Cambridge were shortly to detect radio pulses from stars that are now believed to be highly magnetized, rapidly spinning neutron stars, known as pulsars.
 
In 1965, [[Antony Hewish]] and [[Samuel Okoye]] discovered "an unusual source of high radio brightness temperature in the [[Crab Nebula]]".<ref>{{cite journal|journal=Nature| volume=207|issue=4992| pages=59| title=Evidence of an unusual source of high radio brightness temperature in the Crab Nebula| author=Hewish and Okoye| doi=10.1038/207059a0| year=1965|last2=Okoye|first2=S. E.|bibcode = 1965Natur.207...59H }}</ref> This source turned out to be the [[Crab pulsar|Crab Nebula neutron star]] that resulted from the great [[SN 1054|supernova of 1054]].
 
In 1967, [[Iosif Shklovsky]] examined the X-ray and optical observations of [[Scorpius X-1]] and correctly concluded that the radiation comes from a neutron star at the stage of [[accretion (astrophysics)|accretion]].<ref>{{Cite journal | last=Shklovsky | first=I.S. | title=On the Nature of the Source of X-Ray Emission of SCO XR-1 | journal=Astrophys. J. | volume=148 | issue=1 | pages=L1–L4 | date=April 1967 | doi=10.1086/180001 | postscript=<!--None-->|bibcode = 1967ApJ...148L...1S }}</ref>
 
In 1967, [[Jocelyn Bell Burnell|Jocelyn Bell]] and [[Antony Hewish]] discovered regular radio pulses from [[CP 1919]]. This [[pulsar]] was later interpreted as an isolated, rotating neutron star. The energy source of the pulsar is the rotational energy of the neutron star. The majority of known neutron stars (about 2000, as of 2010) have been discovered as pulsars, emitting regular radio pulses.
 
In 1971, [[Riccardo Giacconi]], Herbert Gursky, Ed Kellogg, R. Levinson, E. Schreier, and H. Tananbaum discovered 4.8 second pulsations in an X-ray source in the [[constellation]] [[Centaurus]], [[Centaurus X-3|Cen X-3]]. They interpreted this as resulting from a rotating hot neutron star. The energy source is gravitational and results from a [[Accretion (astrophysics)|rain of gas falling]] onto the surface of the [[Accretion-powered pulsar|neutron star]] from a [[companion star]] or the [[interstellar medium]].
 
In 1974, [[Antony Hewish]] was awarded the [[Nobel Prize in Physics]] "for his decisive role in the discovery of pulsars" without [[Jocelyn Bell]] who shared in the discovery.
 
In 1974, [[Joseph Hooton Taylor, Jr.|Joseph Taylor]] and [[Russell Hulse]] discovered the first binary pulsar, [[PSR B1913+16]], which consists of two neutron stars (one seen as a pulsar) orbiting around their center of mass.  [[Einstein]]'s general theory of [[General relativity|relativity]] predicts that massive objects in short binary orbits should emit [[gravitational waves]], and thus that their orbit should decay with time.  This was indeed observed, precisely as general relativity predicts, and in 1993, Taylor and Hulse were awarded the [[Nobel Prize in Physics]] for this discovery.
 
In 1982, [[Don Backer]] and colleagues discovered the first [[millisecond pulsar]], [[PSR B1937+21]]. This objects spins 642 times per second, a value that placed fundamental constraints on the mass and radius of neutron stars. Many millisecond pulsars were later discovered, but PSR B1937+12 remained the fastest-spinning known pulsar for 24 years, until [[PSR J1748-2446ad]] was discovered.
 
In 2003, [[Marta Burgay]] and colleagues discovered the first double neutron star system where both components are detectable as pulsars, [[PSR J0737-3039]]. The discovery of this system allows a total of 5 different tests of general relativity, some of these with unprecedented precision.
 
In 2010, [[Paul Demorest]] and colleagues measured the mass of the [[millisecond pulsar]] [[PSR J1614–2230]] to be 1.97±0.04 [[solar mass]]es, using [[Shapiro delay]].<ref>{{cite journal | doi= 10.1038/nature09466 | last1= Demorest | first1= PB | authorlink= Demorest, Paul B. et al. | last2= Pennucci | first2= T | last3= Ransom | first3= SM | last4= Roberts | first4= MS | last5= Hessels | first5= JW | title= A two-solar-mass neutron star measured using Shapiro delay |journal = Nature | volume= 467 | issue=7319 | pages=1081–1083 | bibcode = 2010Natur.467.1081D | year= 2010 | pmid= 20981094|arxiv = 1010.5788 }}</ref>  This was substantially higher than any previously measured neutron star mass (1.67 solar masses, see [[PSR J1903+0327]]), and places strong constraints on the interior composition of neutron stars.
 
In 2013, [[John Antoniadis]] and colleagues measured the mass of [[PSR J0348+0432]] to be 2.01±0.04 [[solar mass]]es, using [[white dwarf]] spectroscopy
.<ref>{{cite journal | doi= 10.1126/science.1233232 | last1= Antoniadis | first1= J | authorlink= Antoniadis, John. et al. | title= A Massive Pulsar in a Compact Relativistic Binary |journal = Science | volume= 340 | number=6131 | bibcode = 2013Sci...340..448A2010 | year= 2012 |arxiv = 1304.6875}}</ref> This confirmed the existence of such massive stars using a different method. Furthermore, this allowed, for the first time, a test of [[general relativity]] using such
a massive neutron star.
 
==Rotation==
Neutron stars rotate extremely rapidly after their creation due to the conservation of angular momentum; like spinning ice skaters pulling in their arms, the slow rotation of the original star's core speeds up as it shrinks. A newborn neutron star can rotate several times a second; sometimes, the neutron star absorbs orbiting matter from a companion star, increasing the rotation to [[Millisecond pulsar|several hundred times per second]], reshaping the neutron star into an [[oblate spheroid]].
 
Over time, neutron stars slow down ([[Stellar spin-down|spin down]]) because their rotating magnetic fields radiate energy; older neutron stars may take several seconds for each revolution.
 
The rate at which a neutron star slows its rotation is usually constant and very small: the observed rates of decline are between 10<sup>−10</sup> and 10<sup>−21</sup> seconds for each rotation. Therefore, for a typical slow down rate of 10<sup>−15</sup> seconds per rotation, a neutron star now rotating in 1 second will rotate in 1.000003 seconds after a century, or 1.03 seconds after 1 million years.
[[Image:2004 stellar quake full.jpg|thumb|right|350px|NASA artist's conception of a "[[Starquake (astrophysics)#Starquake|starquake]]", or "stellar quake".]]
Sometimes a neutron star will ''[[Neutron star spin-up|spin up]]'' or undergo a ''[[glitch (astronomy)|glitch]]'', a sudden small increase of its rotation speed. Glitches are thought to be the effect of a [[starquake (astrophysics)|starquake]]&nbsp;— as the rotation of the star slows down, the shape becomes more spherical. Due to the stiffness of the "neutron" crust, this happens as discrete events when the crust ruptures, similar to tectonic earthquakes. After the starquake, the star will have a smaller equatorial radius, and since angular momentum is conserved, rotational speed increases. Recent work, however, suggests that a starquake would not release sufficient energy for a neutron star glitch; it has been suggested that glitches may instead be caused by transitions of vortices in the superfluid core of the star from one metastable energy state to a lower one.<ref>{{cite web| url=http://physicsworld.com/cws/article/print/1756| date=January 1, 1998| title=Pulsars, glitches and superfluids| publisher=Physicsworld.com| first=M Ali| last= Alpar}}</ref>
 
Neutron stars have been observed to "pulse" radio and x-ray emissions believed to be caused by particle acceleration near the [[Poles of astronomical bodies#Magnetic poles|magnetic poles]], which need not be aligned with the rotation axis of the star. Through mechanisms not yet entirely understood, these particles produce coherent beams of radio emission. External viewers see these beams as pulses of radiation whenever the magnetic pole sweeps past the line of sight. The pulses come at the same rate as the rotation of the neutron star, and thus, appear periodic. Neutron stars which emit such pulses are called [[pulsar]]s.
 
The most rapidly rotating neutron star currently known, [[PSR J1748-2446ad]], rotates at 716 rotations per second.<ref>[http://arxiv.org/abs/astro-ph/0601337 [astro-ph/0601337&#93; A Radio Pulsar Spinning at 716 Hz<!-- Bot generated title -->]</ref> A recent paper reported the detection of an X-ray burst oscillation (an indirect measure of spin) at 1122&nbsp;Hz from the neutron star XTE J1739-285.<ref>[http://www.journals.uchicago.edu/cgi-bin/resolve?doi=10.1086/513270 University of Chicago Press – Millisecond Variability from XTE J1739285 – 10.1086/513270<!-- Bot generated title -->]</ref> However, at present, this signal has only been seen once, and should be regarded as tentative until confirmed in another burst from this star.
 
==Population and distances==
At present, there are about 2000 known neutron stars in the [[Milky Way]] and the [[Magellanic Clouds]], the majority of which have been detected as radio [[pulsar]]s. Neutron stars are most concentrated along the disk of the Milky Way although the spread perpendicular to the disk is large because the [[supernova]] explosion process can impart high speeds (400&nbsp;km/s) to the newly created neutron star.
 
Some of the closest neutron stars are [[RX J1856.5-3754]] about 400 [[light year]]s away and [[PSR J0108-1431]] at about 424 light years.<ref name="aaa496">{{cite journal
| author=Posselt, B.; Neuhäuser, R.; Haberl, F.
| title=Searching for substellar companions of young isolated neutron stars
| journal=Astronomy and Astrophysics | volume=496| issue=2
| year=2009 | pages=533–545 | month=March | doi=10.1051/0004-6361/200810156
| bibcode=2009A&A...496..533P |arxiv = 0811.0398 }}</ref> Another nearby neutron star that was detected transiting the backdrop of the constellation Ursa Minor has been catalogued as [[1RXS J141256.0+792204]]. This rapidly moving object, nicknamed "Calvera" by its Canadian and American discoverers, was discovered using the [[ROSAT/Bright Source Catalog]]. Initial measurements placed its distance from Earth at 200 to 1,000 light years away, with later claims at about 450 light-years.
 
==Binary neutron stars==
About 5% of all known neutron stars are members of a [[binary system (astronomy)|binary system]]. The formation and evolution scenario of binary neutron stars is a rather exotic and complicated process.<ref>Tauris & van den Heuvel (2006), in Compact Stellar X-ray Sources. Eds. Lewin and van der Klis, Cambridge University Press http://adsabs.harvard.edu/abs/2006csxs.book..623T</ref> The companion stars may be either ordinary [[star]]s, [[white dwarf]]s or other neutron stars. According to modern theories of binary evolution it is expected that neutron stars also exist in binary systems with [[black hole]] companions. Such binaries are expected to be prime sources for emitting [[gravitational waves]]. Neutron stars in binary systems often emit [[X-rays]] which is caused by the heating of material (gas) [[accretion (astrophysics)|accreted]] from the companion star. Material from the outer layers of a (bloated) companion star is sucked towards the neutron star as a result of its very strong gravitational field. As a result of this process binary neutron stars may also coalesce into [[black hole]]s if the accretion of mass takes place under extreme conditions.<ref>Compact Stellar X-ray Sources (2006). Eds. Lewin and van der Klis, Cambridge University</ref> It has been proposed that coalescence of binaries consisting of two neutron stars may be responsible for producing [[Gamma-ray burst#Short gamma-ray bursts|short gamma-ray bursts]]. Such events may also be responsible for creating all [[chemical element]]s beyond [[iron]],<ref>{{cite web
|url=http://www.cnn.com/2013/07/20/opinion/urry-gold-stars/index.html
|title=Gold comes from stars
|first=Meg
|last=Urry
|authorlink=Meg Urry
|publisher=CNN
|date=July 20, 2013}}</ref> as opposed to the [[supernova nucleosynthesis]] theory.
 
==Subtypes==
* Neutron star
** Protoneutron star (PNS), theorized.<ref>[http://www.astro.princeton.edu/~burrows/eos.wind.thermal/wind.html Neutrino-Driven Protoneutron Star Winds], Todd A. Thompson.</ref>
** [[Radio-quiet neutron star]]s
** Radio loud neutron star
*** [[Pulsar|Single pulsar]]s–general term for neutron stars that emit directed pulses of radiation towards us at regular intervals (due to their strong magnetic fields).
**** [[Rotation-powered pulsar]] ''("radio pulsar")''
***** [[Magnetar]]–a neutron star with an extremely strong magnetic field (1000 times more than a regular neutron star), and long rotation periods (5 to 12 seconds).
****** [[Soft gamma repeater]] (SGR)
****** [[Anomalous X-ray pulsar]] (AXP)
*** [[Binary pulsar]]s
**** [[Low-mass X-ray binaries]] (LMXB)
**** [[Intermediate-mass X-ray binaries]] (IMXB)
**** [[High-mass X-ray binaries]] (HMXB)
**** [[Accretion-powered pulsar]] ''("X-ray pulsar")''
***** [[X-ray burster]]–a neutron star with a low mass binary companion from which matter is accreted resulting in irregular bursts of energy from the surface of the neutron star.
***** [[Millisecond pulsar]] (MSP) ''("recycled pulsar")''
****** Sub-millisecond pulsar<ref>{{cite journal|bibcode=1989PThPh..81.1006N|title=Binary Sub-Millisecond Pulsar and Rotating Core Collapse Model for SN1987A |last=Nakamura|doi=10.1143/PTP.81.1006|journal=Progress of Theoretical Physics |first=T.|volume=81|issue=5|pages=1006 |year=1989}}</ref>
** [[Exotic star]]
*** [[Quark star]]–currently a hypothetical type of neutron star composed of [[quark matter]], or [[strange matter]]. As of 2008, there are three candidates.
*** [[Electroweak star]]–currently a hypothetical type of extremely heavy neutron star, in which the quarks are converted to leptons through the electroweak force, but the gravitational collapse of the star is prevented by radiation pressure. As of 2010, there is no evidence for their existence.
*** [[Preon star]]–currently a hypothetical type of neutron star composed of [[preon matter]]. As of 2008, there is no evidence for the existence of [[preon]]s.
 
==Giant nucleus==
A neutron star has some of the properties of an [[atomic nucleus]], including density and being composed of [[nucleon]]s. In popular scientific writing, neutron stars are therefore sometimes described as giant nuclei. However, in other respects, neutron stars and atomic nuclei are quite different. In particular, a nucleus is held together by the [[strong interaction]], whereas a neutron star is held together by [[gravity]]. It is generally more useful to consider such objects as [[star]]s.
 
==Examples of neutron stars==
* [[PSR J0108-1431]] – closest neutron star
* [[LGM-1]] – the first recognized radio-pulsar
* [[PSR B1257+12]] – the first neutron star discovered with planets (a millisecond pulsar)
* [[SWIFT J1756.9-2508]] – a millisecond pulsar with a stellar-type companion with planetary range mass (below brown dwarf)
* [[PSR B1509-58]] source of the "Hand of God" photo shot by the [[Chandra X-ray Observatory]].
 
==See also==
{{Portal|Star}}
<div style="-moz-column-count:2; column-count:2;">
* [[Magnetar]]
* [[Millisecond pulsar]]
* [[Neutron]]
* [[Neutronium]], [[Neutron-degenerate matter]]
* [[Preon matter]], [[Preon-degenerate matter]]
* [[Pulsar]]
* [https://science.nrao.edu/facilities/gbt Pulsar in Triple Stellar System]<ref>{{cite web
| title      = Pulsar in Triple Stellar System -- (a featured section that is part of the web page about The National Radio Astronomy Observatory in Green Bank, West Virginia)
| url        = https://science.nrao.edu/facilities/gbt
| accessdate  = January 29, 2014
| quote      = Astronomers using the National Science Foundation's Green Bank Telescope (GBT) have discovered a unique stellar system of two white dwarf stars and a superdense neutron star, all packed within a space smaller than Earth's orbit around the Sun. The closeness of the stars, combined with their nature, has allowed the scientists to make the best measurements yet of the complex gravitational interactions in such a system.  In addition, detailed studies of this system may provide a key clue for resolving one of the principal outstanding problems of fundamental physics -- the true nature of gravity.
}}</ref>
* [[Quark matter]], [[Quark-degenerate matter]]
* [[Radio quiet neutron stars]]
* [[Rotating radio transients]]
* [[The Magnificent Seven (neutron stars)]]
</div>
 
==Notes==
{{reflist|group=lower-alpha}}
 
==References==
{{Reflist|2}}
 
{{Refbegin}}
* {{cite web | url=http://scienceweek.com/2004/sb040806-1.htm | title=ASTROPHYSICS: ON OBSERVED PULSARS | work=scienceweek.com | accessdate=6 August 2004 }}
* {{cite book | title=Compact Stars | author=Norman K. Glendenning, R. Kippenhahn, I. Appenzeller, G. Borner, M. Harwit | year=2000 | edition=2nd }}
* {{cite journal | title= Evidence for 1122 Hz X-Ray Burst Oscillations from the Neutron-Star X-Ray Transient XTE J1739-285 | author1=Kaaret | author2=Prieskorn | author3=in 't Zand | author4=Brandt | author5=Lund | author6=Mereghetti | author7=Gotz | author8=Kuulkers | author9=Tomsick | doi=10.1086/513270 | year=2006 | journal= The Astrophysical Journal | volume= 657 | issue= 2 | pages= L97 | arxiv=astro-ph/0611716 |bibcode = 2007ApJ...657L..97K }}
{{Refend}}
 
==External links==
{{Commons category|Neutron stars}}
* [http://www.astro.umd.edu/~miller/nstar.html Introduction to neutron stars]
* [http://arxiv.org/abs/nucl-th/0309041 Neutron Stars for Undergraduates] and its [http://t16web.lanl.gov/Silbar/NStarErrata.html Errata]
* [http://imagine.gsfc.nasa.gov/docs/science/know_l2/pulsars.html NASA on pulsars]
* "[http://spacedaily.com/reports/NASA_Sees_Hidden_Structure_Of_Neutron_Star_In_Starquake.html NASA Sees Hidden Structure Of Neutron Star In Starquake]". SpaceDaily.com. April 26, 2006
* "[http://newscientistspace.com/article.ns?id=dn9397&feedId=online-news_rss20 Mysterious X-ray sources may be lone neutron stars]". ''New Scientist''.
* "[http://space.newscientist.com/article/dn9428-massive-neutron-star-rules-out-exotic-matter.html Massive neutron star rules out exotic matter]". ''New Scientist''. According to a new analysis, exotic states of matter such as free quarks or BECs do not arise inside neutron stars.
* "[http://space.newscientist.com/article/dn9730-neutron-star-clocked-at-mindboggling-velocity.html Neutron star clocked at mind-boggling velocity]". ''New Scientist''. A neutron star has been clocked traveling at more than 1500 kilometers per second.
 
{{Neutron star}}
{{Star}}
{{Supernovae}}
 
{{DEFAULTSORT:Neutron Star}}
[[Category:Neutron stars| ]]
[[Category:Neutron|Star]]
[[Category:Star types]]
[[Category:Exotic matter]]

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