Einstein ring
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Gravitational Lensing | ||||
Formalism Weak lensing Microlensing Einstein ring
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In observational astronomy an Einstein ring is the deformation of the light from a source (such as a galaxy or star) into a ring through gravitational lensing of the source's light by an object with an extremely large mass (such as another galaxy, or a black hole). This occurs when the source, lens and observer are all aligned. The first complete Einstein ring, designated B1938+666, was discovered by collaboration between astronomers at the University of Manchester and Nasa's Hubble Space Telescope in 1998.[1]
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[edit] Introduction
Gravitational lensing is predicted by Albert Einstein's theory of General relativity. Instead of light from a source traveling in a straight line (in three dimensions), it is bent by the presence of a massive body, which distorts spacetime. An Einstein Ring is a special case of gravitational lensing, caused by the exact alignment of the source, lens and observer. This results in a symmetry around the lens, causing a ring-like structure.
The size of an Einstein ring is given by the Einstein radius. In radians, it is
where
- G is the gravitational constant,
- M is the mass of the lens,
- c is the speed of light,
- dL is the angular diameter distance to the lens,
- dS is the angular diameter distance to the source, and
- dLS is the angular diameter distance between the lens and the source.
Note that, over cosmological distances in general.
[edit] History
The bending of light by a gravitational body was predicted by Einstein in 1912, a few years before the publication of General Relativity in 1916 (see Renn et al. 1997). The ring effect was first mentioned in academic literature by Orest Chwolson in 1924. Albert Einstein remarked upon this effect in 1936 in a paper prompted by a letter by a Czech engineer, R W Mandl [1], but stated
- "Of course, there is no hope of observing this phenomenon directly. First, we shall scarcely ever approach closely enough to such a central line. Second, the angle β will defy the resolving power of our instruments." (Science vol 84 p 506 1936).
In this statement, β is the Einstein Radius currently denoted by θE (see later). However, Einstein was only considering the chance of observing Einstein rings produced by stars, which is low; however, the chance of observing those produced by larger lenses such as galaxies or black holes is higher since the angular size of an Einstein ring increases with the mass of the lens.
[edit] Known Einstein rings
Hundreds of gravitational lenses are currently known. About half a dozen of them are partial Einstein rings with diameters up to an arcsecond, although as either the mass distribution of the lenses is not perfectly axially symmetrical, or the source, lens and observer are not perfectly aligned, we have yet to see a perfect Einstein ring. Most rings have been discovered in the radio range.
Name | Location (RA, dec) | Radius | Arc size | Optical/radio | Discovery |
---|---|---|---|---|---|
FOR J0332-3557 | 03h:32m:59s:94, -35°57'51".7, J2000 | 1".48 | Partial, 260° | Radio | Cabanac (2005) |
SDSSJ0946+1006 | 09h 46m 56.s68, +10° 06' 52."6 J2000 | Optical | Gavazzi (2008) | ||
MG1131 + 0456 |
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[edit] Extra rings
Using the Hubble Space Telescope, a double ring has been found by Raphael Gavazzi of the STScI and Tommaso Treu of the University of California, Santa Barbara. This arises from the light from three galaxies at distances of 3, 6 and 11 billion light years. Such rings help in understanding the distribution of dark matter, dark energy, the nature of distant galaxies, and the curvature of the universe. The odds of finding such a double ring are 1 in 10,000. Sampling 50 suitable double rings would provide astronomers with a more accurate measurement of the dark matter content of the universe and the equation of state of the dark energy to within 10 percent precision.[2]
[edit] A simulation
To the right is a simulation depicting a zoom on a Schwarzschild black hole in front of the Milky Way. The first Einstein ring corresponds to the most distorted region of the picture and is clearly depicted by the galactic disc. The zoom then reveals a series of 4 extra rings, increasingly thinner and closer to the black hole shadow. They are easily seen through the multiple images of the galactic disk. Odd rings correspond to points which are behind the black hole (from the observer point of view) and correspond here to the bright yellow region of the galactic disc (close to the galactic center), whereas even rings correspond to images of regions which are behind the observer, which appear bluer since the corresponding part of the galactic disk is dimmer here.
[edit] References
- ^ http://query.nytimes.com/gst/fullpage.html?res=9906EFDF103BF932A05750C0A96E958260
- ^ Hubble Finds Double Einstein Ring. http://hubblesite.org. Space Telescope Science Institute. Retrieved on 2008-01-26.
[edit] Journals
- Cabanac, R. A.; et al. (2005). "Discovery of a high-redshift Einstein ring". Astron.Astrophys. 436: L21—L25. (refers to FOR J0332-3357)
- Chwolson, O (1924). "Über eine mögliche Form fiktiver Doppelsterne". Astronomische Nachrichten 221: 329. (The first paper to propose rings)
- Einstein, Albert (1936). "Lens-like Action of a Star by the Deviation of Light in the Gravitational Field". Science 84: 506—507. (The famous Einstein Ring paper)
- Renn, Jurgen; Tilman Sauer and John Stachel (1997). "The Origin of Gravitational Lensing: A Postscript to Einstein's 1936 Science paper". Science 275: 184—186. doi: .
[edit] News
- Barbour, Jeff. "Nearly perfect Einstein ring discovered", Universe Today, 2005-04-29. Retrieved on 2006-06-15. (refers to FOR J0332-3357)
- "Hubble Finds Double Einstein Ring", Science Daily, 2008-01-12. Retrieved on 2008-01-14.
[edit] See also
[edit] Further reading
- Kochanek, C.S.; C.R. Keeton and B.A. McLeod (2001). "The Importance of Einstein Rings". The Astrophysical Journal 547: 50—59.