CfA2 Great Wall

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The Great Wall (also called Coma Wall), sometimes specifically referred to as the CfA2 Great Wall, is an immense galaxy filament. It is one of the largest known superstructures in the observable universe.

Contents

This structure was discovered c. 1989 by a team of American astronomers led by Margaret J. Geller and John Huchra while analyzing data gathered by the second CfA Redshift Survey of the Center for Astrophysics | Harvard & Smithsonian (CfA).

Characteristics

The term "Great" has been added to distinguish it as an even larger type compared to standard galaxy walls.

The CfA2 Great Wall has the maximum dimensions of either 500 million or 750 million light years depending on the figure and the reference used.[ citation needed ] It is 200 million light years in width and about 16 million light years in thickness. Its nearest point is about 300 million light years from Earth, while its furthest point is 550 million light years away. It consists of three massive galaxy superclusters: Hercules, Coma, and Leo.

The CfA2 Great Wall includes the Coma Filament.

Components

The Great Wall includes clusters Hercules, Coma and Leo on the right of this view of the local universe. Nearsc.gif
The Great Wall includes clusters Hercules, Coma and Leo on the right of this view of the local universe.

It was discovered in 1989 by Margaret Geller and John Huchra based on redshift survey data from the CfA Redshift Survey. [1]

It is not known how much further the wall extends due to the light absorption in the plane of the Milky Way galaxy where Earth is located. The gas and dust from the Milky Way (known as the Zone of Avoidance) obscure the view of astronomers and have so far made it impossible to determine if the wall ends or continues on further than they can currently observe.

In the standard model of the evolution of the universe, such structures as the Great Wall form along and follow web-like strings of dark matter. [2] It is thought that this dark matter dictates the structure of the Universe on the grandest of scales. Dark matter gravitationally attracts baryonic matter, and it is this "normal" matter that astronomers see forming long, thin walls of super-galactic clusters.

See also

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References

  1. Geller, Margaret J.; John P. Huchra (1989-11-17). "Mapping the Universe". Science. 246 (4932): 897–903. Bibcode:1989Sci...246..897G. doi:10.1126/science.246.4932.897. PMID   17812575. S2CID   31328798 . Retrieved 2011-05-03.
  2. Riordan, Michael; David N. Schramm (1991). Shadows of Creation: Dark Matter and the Structure of the Universe . W H Freeman & Co (Sd). ISBN   978-0-7167-2157-4.