Galaxy groups and clusters

Galaxy groups and clusters


Galaxy groups and clusters are the largest known gravitationally bound objects to have arisen thus far in the process of cosmic structure formation.[1] They form the densest part of the large scale structure of the universe. In models for the gravitational formation of structure with cold dark matter, the smallest structures collapse first and eventually build the largest structures, clusters of galaxies. Clusters are then formed relatively recently between 10 billion years ago and now. Groups and clusters may contain from ten to thousands of galaxies. The clusters themselves are often associated with larger, non-gravitationally bound, groups called superclusters.

Contents

Groups of galaxies

Groups of galaxies are the smallest aggregates of galaxies. They typically contain no more than 50 galaxies in a diameter of 1 to 2 megaparsecs (Mpc) (see 1022 m for distance comparisons). Their mass is approximately 1013 solar masses. The spread of velocities for the individual galaxies is about 150 km/s. However, this definition should be used as a guide only, as larger and more massive galaxy systems are sometimes classified as galaxy groups.

Our own galaxy, the Milky Way, is contained in the Local Group of galaxies, which contains more than 40 galaxies.[2]

Clusters of galaxies

Rich scattering of galaxies was captured using the Wide Field Imager attached to the MPG/ESO 2.2-metre telescope.
Galaxy cluster ACO 3341.

Clusters are larger than groups, although there is no sharp dividing line between the two. When observed visually, clusters appear to be collections of galaxies held together by mutual gravitational attraction. However, their velocities are too large for them to remain gravitationally bound by their mutual attractions, implying the presence of either an additional invisible mass component, or an additional attractive force besides gravity. X-ray studies have revealed the presence of large amounts of intergalactic gas known as the intracluster medium. This gas is very hot, between 107K and 108K, and hence emits X-rays in the form of bremsstrahlung and atomic line emission. The total mass of the gas is greater than that of the galaxies by roughly a factor of two. However this is still not enough mass to keep the galaxies in the cluster. Since this gas is in approximate hydrostatic equilibrium with the overall cluster gravitational field, the total mass distribution can be determined. It turns out the total mass deduced from this measurement is approximately six times larger than the mass of the galaxies or the hot gas. The missing component is known as dark matter and its nature is unknown. In a typical cluster perhaps only 5% of the total mass is in the form of galaxies, maybe 10% in the form of hot X-ray emitting gas and the remainder is dark matter. Brownstein and Moffat[3] use a theory of modified gravity to explain X-ray cluster masses without dark matter. Observations of the Bullet Cluster are the strongest evidence for the existence of dark matter;[4][5][6] however, Brownstein and Moffat[7] have shown that their modified gravity theory can also account for the properties of the cluster.

Observational methods

Galaxy Cluster LCDCS-0829 acting like a giant magnifying glass. This strange effect is called gravitational lensing.

Clusters of galaxies have been found in surveys by a number of observational techniques and have been studied in detail using many methods:

  • Optical or infrared: The individual galaxies of clusters can be studied through optical or infrared imaging and spectroscopy. Galaxy clusters are found by optical or infrared telescopes by searching for overdensities, and then confirmed by finding several galaxies at a similar redshift. Infrared searches are more useful for finding more distant (higher redshift) clusters.
  • X-ray: The hot plasma emits X-rays which can be detected by X-ray telescopes. The cluster gas can be studied using both X-ray imaging and X-ray spectroscopy. Clusters are quite prominent in X-ray surveys and along with AGN are the brightest X-ray emitting extragalactic objects.
  • Radio: A number of diffuse structures emitting at radio frequencies have been found in clusters. Groups of radio sources (which may include diffuse structures or AGN have been used as tracers of cluster location. At high redshift imaging around individual radio sources (in this case AGN) has been used to detect proto-clusters (clusters in the process of forming).
  • Sunyaev-Zel'dovich effect: The hot electrons in the intracluster medium scatter radiation from the cosmic microwave background through inverse Compton scattering. This produces a "shadow" in the observed cosmic microwave background at some radio frequencies.
  • Gravitational lensing: Clusters of galaxies contain enough matter to distort the observed orientations of galaxies behind them. The observed distortions can be used to model the distribution of dark matter in the cluster.

Temperature and density

The Most Distant Mature Galaxy Cluster[8] taken with ESO's Very Large Telescope in Chile and the NAOJ’s Subaru telescope in Hawaii

Clusters of galaxies are the most recent and most massive objects to have arisen in the hierarchical structure formation of the universe and the study of clusters tells one about the way galaxies form and evolve. Clusters have two important properties: their masses are large enough to retain any energetic gas ejected from member galaxies and the thermal energy of the gas within the cluster is observable within the X-Ray bandpass. The observed state of gas within a cluster is determined by a combination of shock heating during accretion, radiative cooling, and thermal feedback triggered by that cooling. The density, temperature, and substructure of the intracluster X-Ray gas therefore represents the entire thermal history of cluster formation. To better understand this thermal history one needs to study the entropy of the gas because entropy is the quantity most directly changed by increasing or decreasing the thermal energy of intracluster gas.[citation needed]

See also

References

  1. ^ Voit, G.M.; "Tracing cosmic evolution with clusters of galaxies"; Reviews of Modern Physics, vol. 77, Issue 1, pp. 207-258
  2. ^ Mike Irwin. "The Local Group". http://www.ast.cam.ac.uk/~mike/local_more.html. Retrieved 2009-11-07. 
  3. ^ Brownstein, J. R.; Moffat, J. W. (2006). "Galaxy Cluster Masses Without Non-Baryonic Dark Matter". Monthly Notices of the Royal Astronomical Society 367: 527–540. arXiv:astro-ph/0507222. Bibcode 2006MNRAS.367..527B. doi:10.1111/j.1365-2966.2006.09996.x. 
  4. ^ Markevitch; Gonzalez; Clowe; Vikhlinin; David; Forman; Jones; Murray et al. (2003). "Direct constraints on the dark matter self-interaction cross-section from the merging galaxy cluster 1E0657-56". Astrophys.J.606:819-824,2004 606 (2): 819–824. arXiv:astro-ph/0309303. Bibcode 2004ApJ...606..819M. doi:10.1086/383178. 
  5. ^ Coe, Dan; Benítez, Narciso; Broadhurst, Tom; Moustakas, Leonidas A. (2010). "A High-resolution Mass Map of Galaxy Cluster Substructure: LensPerfect Analysis of A1689". The Astrophysical Journal 723: 1678. arXiv:arXiv:1005.0398. Bibcode 2010ApJ...723.1678C. doi:10.1088/0004-637X/723/2/1678. 
  6. ^ McDermott, Samuel D.; Yu, Hai-Bo; Zurek, Kathryn M. (2011). "Turning off the lights: How dark is dark matter?". Physical Review D 83: 063509. arXiv:arXiv:1011.2907. Bibcode 2011PhRvD..83f3509M. doi:10.1103/PhysRevD.83.063509. 
  7. ^ Brownstein, J. R.; Moffat, J. W. (2007). "The Bullet Cluster 1E0657-558 evidence shows Modified Gravity in the absence of Dark Matter". Monthly Notices of the Royal Astronomical Society 382: 29–47. arXiv:astro-ph/0702146v3. Bibcode 2007MNRAS.382...29B. doi:10.1111/j.1365-2966.2007.12275.x. 
  8. ^ "The Most Distant Mature Galaxy Cluster". ESO Science Release. ESO. http://www.eso.org/public/news/eso1108/. Retrieved 9 March 2011. 

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