- Large-scale structure of the cosmos
In
physical cosmology , the term large-scale structure refers to the characterization of observable distributions ofmatter andlight on the largest scales (typically on the order of billions oflight-year s). Sky surveys and mappings of the variouswavelength bands ofelectromagnetic radiation (in particular 21-cm emission) have yielded much information on the content and character of theuniverse 's structure. The organization of structure appears to follow as a hierarchical model with organization up to the scale ofsupercluster s and filaments. Larger than this, there seems to be no continued structure, a phenomenon which has been referred to as the End of Greatness.Walls, filaments and voids
thumb|300px|left|DTFE reconstruction of the inner parts of the 2dF Galaxy Redshift Surveyastrophysics on that scale.Star s are organised into galaxies, which in turn form clusters andsupercluster s that are separated by immense voids. Prior to 1989, it was commonly assumed that virialized galaxy clusters were the largest structures in existence, and that they were distributed more or less uniformly throughout the universe in every direction. However, based onredshift survey data, in1989 Margaret Geller andJohn Huchra discovered the "Great Wall," a sheet of galaxies more than 500 millionlight-year s long and 200 million wide, but only 15 million light-years thick. The existence of this structure escaped notice for so long because it requires locating the position of galaxies in three dimensions, which involves combining location information about the galaxies with distance information fromredshift s.In April 2003, another large-scale structure was discovered, theSloan Great Wall . However, technically it is not a 'structure', since the objects in it are not gravitationally related with each other but only appear this way, caused by the distance measurement that was used. One of the biggest voids in space is theCapricornus void , with an estimated diameter of 230 million light years [ [http://www.atlasoftheuniverse.com/nearsc.html The Nearest Superclusters ] ] . In August 2007, a possible supervoid was detected in the constellation Eridanus. [ [http://space.newscientist.com/article/dn12546-biggest-void-in-space-is-1-billion-light-years-across.html Biggest void in space is 1 billion light years across - space - 24 August 2007 - New Scientist Space ] ] It coincides with the 'WMAP Cold Spot', a cold region in the microwave sky that is highly improbable under the currently favored cosmological model. This supervoid could cause the cold spot, but to do so it would have to be improbably big, possibly a billion light-years across.In more recent studies the universe appears as a collection of giant bubble-like voids separated by sheets and filaments of galaxies, with the
supercluster s appearing as occasional relatively dense nodes. This network is clearly visible in the 2dF Galaxy Redshift Survey. In the figure a 3-D reconstruction of the inner parts of the survey is shown, revealing an impressive view on the cosmic structures in the nearby universe. Several superclusters stand out, such as the Sloan Great Wall, the largest structure in the universe known to date.End of Greatness
The "End of Greatness" is an observational scale discovered at roughly 100 Mpc (roughly 300 million
lightyear s) where the lumpiness seen in the large-scale structure of theuniverse is and isotropized as per theCosmological Principle . Thesupercluster s and filaments seen in smaller surveys arerandom ized to the extent that the smooth distribution of the universe is visually apparent. It wasn't until theredshift survey s of the 1990s were completed that this scale could accurately be observed.Observations
Another indicator of large-scale structure is the '
Lyman alpha forest '. This is a collection of absorption lines which appear in thespectral line s of light fromquasar s, which are interpreted as indicating the existence of huge thin sheets of intergalactic (mostlyhydrogen ) gas. These sheets appear to be associated with the formation of new galaxies.Some caution is required in describing structures on a cosmic scale because things are not always as they appear to be. Bending of light by gravitation (gravitational lensing) can result in images which appear to originate in a different direction from their real source. This is caused by foreground objects (such as galaxies) curving the space around themselves (as predicted by
general relativity ), deflecting light rays that pass nearby. Rather usefully, strong gravitational lensing can sometimes magnify distant galaxies, making them easier to detect. Weak lensing (gravitational shear) by the intervening universe in general also subtly changes the observed large-scale structure. In2004 , measurements of this subtle shear show considerable promise as a test of cosmological models.The large-scale structure of the Universe also looks different if one only uses
redshift to measure distances to galaxies. For example, galaxies behind a galaxy cluster will be attracted to it, and so fall towards it, and so be slightly blueshifted (compared to how they would be if there were no cluster); on the near side, things are slightly redshifted. Thus, the environment of the cluster looks a bit squashed if using redshifts to measure distance. An opposite effect works on the galaxies already within the cluster: the galaxies have some random motion around the cluster centre, and when these random motions are converted to redshifts, the cluster will appear elongated. This creates what is known as a "finger of God": the illusion of a long chain of galaxies pointed at the Earth.Astrocartography of our neighborhood
At the centre of the
Hydra supercluster there is a gravitational anomaly, known as theGreat Attractor , which affects the motion of galaxies over a region hundreds of millions of light-years across. These galaxies are allredshift ed, in accordance withHubble's law , indicating that they are receding from us and from each other, but the variations in their redshift are sufficient to reveal the existence of a concentration of mass equivalent to tens of thousands of galaxies.The Great Attractor, discovered in
1986 , lies at a distance of between 150 million and 250 million light-years (250 million is the most recent estimate), in the direction of the Hydra andCentaurus constellation s. In its vicinity there is a preponderance of large old galaxies, many of which are colliding with their neighbours, and/or radiating large amounts of radio waves.Modeling
There is much work in cosmology which attempts to model the large-scale structure of the universe. Using the
big bang model and assumptions about the type of matter that makes up the universe, it is possible to predict the expected distribution of matter, and by comparison with observation work backward to support and refute certain cosmological theories. Currently, observations indicateweasel-word that most of the mass in the universe must be composed ofcold dark matter . Models which assumehot dark matter orbaryonic dark matter do not provide a good fit with observations. The irregularities in the cosmic microwave background radiation and high redshiftsupernova e give complementary approaches to constraining the same models, and there is a growing consensus that these approaches together are giving evidence that we live in anaccelerating universe .Largest structures in the universe
Clickable map
)
circle 334 301 20
Virgo Supercluster circle 351 333 18Hydra Supercluster circle 366 266 29Centaurus Supercluster circle 449 246 31Shapley Supercluster rect 400 273 430 332Coma Supercluster circle 416 163 45Hercules Supercluster circle 465 365 40Leo Superclusters circle 260 184 32Capricornus Void circle 510 218 33Bootes Void circle 533 325 35Ursa Major Supercluster circle 474 445 36Sextans Supercluster rect 224 434 284 532Columba Supercluster rect 145 450 199 571Horologium Supercluster rect 272 312 333 367Perseus-Pisces Supercluster rect 194 265 251 303Sculptor Void rect 97 89 165 150Capricornus Supercluster rect 536 162 583 212Bootes Supercluster rect 462 79 564 152Corona-Borealis Supercluster rect 26 268 120 359Pisces-Cetes Superclusters poly 131 284 213 334 230 310 152 264Sculptor Superclusters rect 237 215 324 278Pavo-Indus Supercluster poly 391 194 409 244 410 281 406 341 395 391 404 413 420 333 429 278 421 225 410 190CfA2 Great Wall desc bottom-left
References
* [http://www.mso.anu.edu.au/2dFGRS/ List of publications of the 2dF Galaxy Redshift Survey]
Notes
Further reading
*
*
** '
The Astrophysical Journal ', Volume 624, Issue 2, pp. 463-484. PDF| [http://www.irish.teledyn.com/pub/Richard%20Gott%20et%20al%20-%20A%20Map%20of%20the%20Universe.pdf A Map of the Universe] |4.86 MB "05/2005" Gott, J. Richard, III; Jurić, Mario; Schlegel, David; Hoyle, Fiona; Vogeley, Michael; Tegmark, Max; Bahcall, Neta; Brinkmann, Jon ; doi|10.1086/428890 bibcode|2005ApJ...624..463GExternal links
* [http://www.mpa-garching.mpg.de/galform/millennium/ "Millennium Simulation" of structure forming] Max Planck Institute of Astrophysics, Garching, Germany
* [http://apod.nasa.gov/apod/ap071107.html The Sloan Great Wall: Largest Known Structure?] on [http://apod.nasa.gov APOD]
* [http://www.space.gs/17-apr-2007-ras.html Hubble, VLT and Spitzer Capture Galaxy Formation in the Early Universe.]
Wikimedia Foundation. 2010.
