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துடிப்பண்டம் (ஆங்கிலத்தில் '''quasar''' (''QUASi-stellAR radio source'') என்பது விண்வெளியில் அமைந்திருக்கும் ஒளி உட்பட வானலை மின்காந்த ஆற்றலை உமிழும் ராட்சத அளவு மூலமாகும். ஒரு துடிப்பண்டத்திலிருந்து உமிழும் ஆற்றல் அதிகளவு பிரகாசம் கொண்ட விண்மீன்கள், ஏன்? பல நூறு அண்டங்களின் கூட்டு ஆற்றலை மீறும்! தொலைநோக்கியில் ஒரு துடிப்பண்டம் ஒரு புள்ளி ஒளிமூலம் போல் தென்ப்டும். துடிப்பண்டங்கள் அதிக சிவப்புப்பெயர்ச்சியை (red shift) பிரதிபலிக்கின்றன. இந்த சிவப்புப்பெயர்ச்சிக்கு துடிப்பண்டங்களின் வெகுதொலைவே காரணம் என கருத்தப்படுகிறது.
Some quasars display rapid changes in [[luminosity]], which implies that they are small (an object cannot change faster than the time it takes light to travel from one end to the other; but see [[quasar J1819+3845]] for another explanation). The highest [[redshift]] currently known for a quasar is 6.4. <ref>{{cite web | title = Three Distant Quasars Found At Edge of the Universe | work = Sloan Digital Sky Survey | url = http://www.sdss.org/news/releases/20030109.quasar.html | accessdate = April 21| accessyear = 2006 }}</ref>
The [[scientific consensus]] is that quasars are powered by [[accretion]] of material onto [[supermassive black holes]] in the nuclei of distant galaxies, making these luminous versions of the general class of objects known as [[active galaxies]]. No other currently known mechanism appears able to explain the vast energy output and rapid variability.
==துடிப்பண்டங்களின் பண்புகள்==
1,00,000ற்கு மேற்பட்ட துடிப்பண்டங்கள் அறியப்பட்டுள்ளன. அனைத்திலும் சிவப்புப் பெயர்ச்சி காணப்பட்டுள்ளன, ranging from 0.06 to the recent maximum of 6.4. Therefore, all known quasars lie at great distances from us, the closest being 240 [[Megaparsec|Mpc]] (780 million [[Light year|ly]]) away and the farthest being 4 [[Gigaparsec|Gpc]] (13 billion ly) away. Most quasars are known to lie above 1.0 Gpc in distance; since light takes such a long time to cover these great distances, we are seeing quasars as they existed long ago — the universe as it was in the distant past.
<!-- Image with unknown copyright status removed: [[Image:HE01514326.jpg|thumb|left|Quasar HE 0151-4326]] -->
Although faint when seen optically, their high [[redshift]] implies that these objects lie at a great distance from us, making quasars the brightest objects in the known universe. The quasar which appears brightest in our sky is the ultraluminous [[3C 273|3C 273]] in the [[constellation]] of [[Virgo]]. It has an average [[apparent magnitude]] of 12.8 (bright enough to be seen through a small [[telescope]]), but it has an [[absolute magnitude]] of −26.7. So from a distance of 10 [[parsec|parsecs]] (about 33 [[light-year]]s), this object would shine in the sky about as bright as our [[sun]]. This quasar's [[luminosity]] is, therefore, about 2 [[trillion]] (2 × 10<sup>12</sup>) times that of our sun, or about 100 times that of the total light of average giant galaxies like our [[Milky Way]].
The hyperluminous [[Quasar APM 08279+5255]] was, when discovered in 1998, given an [[absolute magnitude]] of −32.2, although high resolution imaging with the [[Hubble Space Telescope]] and the 10 m [[Keck Telescope]] reveal that this system is [[gravitational lensing|gravitationally lensed]]. A study of the gravitational lensing in this system suggests that it has been magnified by a factor of ~10. It is still substantially more luminous than nearby quasars such as 3C 273. [[HS 1946+7658]] was thought to have an absolute magnitude of −30.3, but this too was magnified by the [[gravitational lensing]] effect.
Quasars are found to vary in luminosity on a variety of time scales. Some vary in brightness every few months, weeks, days, or hours. This evidence has allowed scientists to theorize that quasars generate and emit their energy from a very small region, since each part of the quasar would have to be in contact with other parts on such a time scale to coordinate the luminosity variations. As such, a quasar varying on the time scale of a few weeks cannot be larger than a few light-weeks across.
Quasars exhibit many of the same properties as active galaxies: [[Radiation]] is nonthermal and some are observed to have jets and lobes like those of [[radio galaxy|radio galaxies]]. Quasars can be observed in many parts of the [[electromagnetic spectrum]] including [[radio waves|radio]], [[infrared]], [[visible light|optical]], [[ultraviolet]], [[X-ray]] and even [[gamma ray]]s. Most quasars are brightest in their rest-frame near-ultraviolet (near the 1218 angstrom Lyman-alpha emission line of hydrogen), but due to the tremendous redshifts of these sources, that peak luminosity has been observed as far to the red as 9000 angstroms, in the near infrared.
==Quasar emission generation==
[[Image:QuasarStarburst.jpg|thumb|right|This view, taken with infrared light, is a false-color image of a quasar-starburst tandem with the most luminous [[starburst (astronomy)|starburst]] ever seen in such a combination. The quasar-starburst was found by a team of researchers from six institutions.]]
Since quasars exhibit properties common to all [[active galaxy|active galaxies]], many scientists have compared the emissions from quasars to those of small active galaxies due to their similarity. The best explanation for quasars is that they are powered by [[supermassive black hole]]s. To create a luminosity of 10<sup>40</sup> [[Watt|W]] (the typical brightness of a quasar), a super-massive black hole would have to consume the material equivalent of 10 stars per year. The brightest known quasars are thought to devour 1000 solar masses of material every year. Quasars are thought to 'turn on' and off depending on their surroundings. One implication is that a quasar would not, for example, continue to feed at that rate for 10 billion years, which nicely explains why there are no nearby quasars. In this framework, after a quasar finishes eating up gas and dust, it becomes an ordinary galaxy.
Quasars also provide some clues as to the end of the [[Big Bang]]'s [[reionization]]. The oldest quasars (z > 4) display a [[Gunn-Peterson trough]] and clearly have absorption regions in front of them indicating that the [[intergalactic medium]] at that time was neutral gas. More recent quasars show no absorption region but rather their spectra contain a spiky area known as the [[Lyman-alpha forest]]. This indicates that the intergalactic medium has undergone reionization into plasma, and that neutral gas exists only in small clouds.
One other interesting characteristic of quasars is that they show evidence of elements heavier than helium. This is taken to mean that galaxies underwent a massive phase of star formation creating [[population III stars]] between the time of the [[Big Bang]] and the first observed quasars. If no evidence for such stars is found and alternative mechanisms for producing heavy elements cannot be found, this may seriously undermine the current views of the universe. Light from these stars may have been observed using [[NASA]]'s [[Spitzer Space Telescope]], although [[as of 2005|as of late 2005]] this interpretation remains to be confirmed.
==துடிப்பண்டங்களின் பார்வையிடல் வரலாறு==
துடிப்பண்டங்களின் இருப்பு 1950களில் முதன்முதல் கண்டறியப்பட்டன. Many were recorded as radio sources with no corresponding visible object. Hundreds of these objects were recorded by [[1960]] and published in the [[Third Cambridge Catalogue]] as astronomers scanned the skies for the optical counterparts. In 1960, radio source [[3C48|3C 48]] was finally tied to an optical object. Astronomers detected what appeared to be a faint blue star at the location of the radio source and obtained its spectrum. Containing many unknown broad emission lines, the anomalous spectrum defied interpretation—a claim by [[John Gatenby Bolton|John Bolton]] of a large redshift was not generally accepted.
In [[1962]] a breakthrough was achieved. Another radio source, [[3C273|3C 273]], was predicted to undergo five [[occultations]] by the [[moon]]. Measurements taken by [[Cyril Hazard]] and John Bolton during one of the occultations using the [[Parkes Radio Telescope]] allowed [[Maarten Schmidt]] to optically identify the object and obtain an [[optical spectrum]] using the 200-inch [[Hale Telescope]] on Mount Palomar. This spectrum revealed the same strange emission lines. Schmidt realised that these were actually spectral lines of hydrogen redshifted at the rate of 15.8 percent. This discovery showed that 3C 273 was receding at a rate of 47,000 km/s. This discovery revolutionized quasar observation and allowed other astronomers to find redshifts from the emission lines from other radio sources. 3C 48 was found to have a redshift of 37% the speed of light (as predicted by John Bolton).
The [[neologism]] "quasar", derived from ''quasi-star'' or a contraction of the more formal term ''quasi-stellar radio source'', came to be used as a descriptor for these puzzling objects. Later it was found that not all (actually only 10% or so) quasars have strong radio emission (are 'radio-loud'). Hence the name 'QSO' (quasi-stellar object) is used (in addition to 'quasar') to refer to these objects, including the 'radio-loud' and the 'radio-quiet' classes.
One great topic of debate during the [[1960s]] was whether quasars were nearby objects or distant objects as implied by their [[redshift]]. It was suggested, for example, that the redshift of quasars was not due to the [[Doppler effect]] but rather to light escaping a deep gravitational well. However a star of sufficient mass to form such a well was believed to be unstable <ref>{{cite journal | author=S. Chandrasekhar | title=The Dynamic Instability of Gaseous Masses Approaching the Schwartzschild Limit in General Relativity | journal=Astrophysical Journal | year=1964 | volume=140 | issue=2 | pages=417–433}}</ref>. Quasars also show unusual spectral emission lines which were previously only seen in hot gaseous nebulae of low density, which would be too diffuse to both generate the observed power and fit within a deep gravitational well <ref>{{cite journal | author=J. Greenstein and M. Schmidt | title=The Quasi-Stellar Radio Sources 3C 48 and 3C | journal=Astrophysical Journal | year=1964 | volume=140 | issue=1 | pages=1–34 }}</ref>. There were also serious concerns regarding the idea of cosmologically distant quasars. One strong argument against them was that they implied energies that were far in excess of known energy conversion processes, including [[nuclear fusion]]. At this time, there were some suggestions that quasars were made of some hitherto unknown form of stable [[antimatter]] and that this might account for their brightness. This objection was removed with the proposal of the [[accretion disc]] mechanism in the [[1970s]], and today the cosmological distance of quasars is accepted by almost all researchers.
In [[1979]] the [[gravitational lens]] effect predicted by [[Einstein]]'s [[General Theory of Relativity]] was confirmed observationally for the first time with images of the double quasar 0957+561. <ref> http://www.astr.ua.edu/keel/agn/q0957.html </ref>
In the [[1980s]], unified models were developed in which quasars were viewed as simply a class of active galaxies, and a general consensus has emerged that in many cases it is simply the viewing angle that distinguishes them from other classes, such as [[blazar]]s and [[radio galaxy|radio galaxies]]. The huge luminosity of quasars is believed to be a result of friction caused by gas and dust falling into the [[accretion disc]]s of supermassive black holes, which can convert about half of the [[mass]] of an object into [[energy]] as compared to a few percent for [[nuclear fusion]] processes.
This mechanism is also believed to explain why quasars were more common in the early universe, as this energy production ends when the supermassive black hole consumes all of the gas and dust near it. This means that it is possible that most galaxies, including our own Milky Way, have gone through an active stage (appearing as a quasar or some other class of active galaxy depending on black hole mass and accretion rate) and are now quiescent because they lack a supply of matter to feed into their central black holes to generate radiation.
==References==
<references />
==External links==
*[http://www.seds.org/~spider/spider/Misc/3c273.html 3C 273, the brightest quasar]
*[http://www.aavso.org/vstar/vsots/ 3C 273: Variable Star Of The Season]
*[http://www.nasa.gov/centers/goddard/news/topstory/2005/universe_objects.html NASA Goddard Space Flight Center: News of light that may be from population III stars]
*[http://www.ebicom.net/~rsf1/qso-rsa.htm QSO Redshift Histograms for Incremental Apparent Magnitude Samples]
*[http://cas.sdss.org/dr4/en/proj/advanced/quasars/query.asp SDSS]
*[http://www.hubblesite.org/go/blackholes Black Holes: Gravity's Relentless Pull] Award-winning interactive multimedia Web site about the physics and astronomy of black holes from the Space Telescope Science Institute
* [http://www.spacedaily.com/reports/Research_Sheds_New_Light_On_Quasars_999.html Research Sheds New Light On Quasars] (SpaceDaily) Jul 26, 2006
==See also==
* [[Active galactic nuclei]] (AGN)
* [[Blazar]]
* [[Supermassive black hole]]
* [[Microquasar]]
[[Category:Quasars| ]]
[[Category:Radio astronomy]]
[[Category:Stellar phenomena]]
[[Category:Uncertain stars]]
[[Category:Star types]]
[[ar:نجم زائف]]
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