* Astronomy

Large galaxy clusters are the universe's metropolises, and for years many astronomers have focused their attention on the crowded "downtowns." However, a new map of some of the largest ancient galactic cities shows that much of the "action" is happening in the cosmic suburbs.
An announcement on this result will be made today (May 28) at the 210th meeting of the American Astronomical Society, in Honolulu, Hawaii. Drs. Gordon Squires, Mark Lacy, and Jason Surace of the Spitzer Science Centre, Pasadena, California are co-investigators on the project.

"The most interesting thing that we've found so far is the incredible amount of activity occurring in galactic suburbia. We see unusually large numbers of galaxies with high star formation rates, producing over 100 new suns per year, and with active central supermassive black holes" - Dr. Lori Lubin, of the University of California at Davis, who is the principal investigator of the Observations of Redshift Evolution in Large Scale Environments (ORELSE) Survey.

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Title: A Compact Cluster of Massive Red Galaxies at a Redshift of 1.51
Authors: P. J. McCarthy, H. Yan (1), R. G. Abraham, E. Mentuch (2), K. Glazebrook (3), L. Yan (4), H.-W. Chen (5), S. E. Persson (1), P. Nair (2), S. Savaglio (6), D. Crampton (7), S. Juneau (8), D. Le Borgne (9), R. G. Carlberg (2), R. O. Marzke (10), I. Jorgensen (11), K. Roth (11), R. Murowinski (2) ((1) Carnegie, (2) Toronto, (3) Swinburn, (4) SSC, (5) Chicago, (6) MPE, (7) HIA, (8) Arizona, (9) Saclay, (10) SFSU, (11) Gemini)

We describe a compact cluster of massive red galaxies at z=1.51 discovered in one of the Gemini Deep Deep Survey (GDDS) fields. Deep imaging with the Near Infrared Camera and Multi Object Spectrometer (NICMOS) on the Hubble Space Telescope reveals a high density of galaxies with red optical to near-IR colours surrounding a galaxy with a spectroscopic redshift of 1.51. Mid-IR imaging with Infrared Array Camera (IRAC) on the Spitzer Space telescope shows that these galaxies have spectral energy distributions that peak between 3.6 and 4.5 microns. Fits to 12-band photometry reveal 12 or more galaxies with spectral shapes consistent with z = 1.51. Most are within ~170 co-moving kpc of the GDDS galaxy. Deep F814W images with the Advanced Camera for Surveys (ACS) on HST reveal that these galaxies are a mix of early-type galaxies, disk galaxies and close pairs. The total stellar mass enclosed within a sphere of 170 kpc in radius is > 8E+11 solar masses. The colours of the most massive galaxies are close to those expected from passive evolution of simple stellar populations (SSP) formed at much higher redshifts. We suggest that several of these galaxies will merge to form a single, very massive galaxy by the present day. This system may represent an example of a short-lived dense group or cluster core typical of the progenitors of massive clusters in the present day and suggests the red sequence was in place in over-dense regions at early times.


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Near-infrared HST imaging reveals a large number of faint galaxies around the central luminous galaxies clustering around GDDS-12-5869

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 An Australian team, led by Sarah Brough of the Swinburne University of Technology used the Gemini South Telescope to find that the most massive galaxies evolve through a variety of mechanisms which are dependent on the mass of their cluster environment. These observations are not consistent with any single model of galaxy formation, presenting a challenge for theorists.
Brightest cluster galaxies (BCGs) are the most massive galaxies known. They are generally red, elliptical type galaxies with remarkably similar brightnesses that are only found near the centres of galaxy clusters. To understand how galaxies form and evolve it is vitally important to understand the formation of these massive galaxies. The uniformity of BCGs suggests that they have experienced similar evolutionary histories and their position at the centres of clusters suggests that their histories must be connected to their environment.
Current models of galaxy formation predict that the stars in these most massive galaxies should have formed more than 12 Billion years ago, while the galaxies themselves should have undergone many dry mergers (without star formation) with other galaxies since that time to build up the very large galaxies we observe today. The models also predict that galaxies in less massive clusters are at an earlier stage in their evolution, so they should have undergone fewer mergers.

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Title: Lyman-break galaxies at z~5 - I. First significant stellar mass assembly in galaxies that are not simply z~3 LBGs at higher redshift
Authors: Aprajita Verma, Matthew D. Lehnert, Natascha M. F¨orster Schreiber, Malcolm N. Bremer, Laura Douglas

We determine the ensemble properties of z~5 Lyman break galaxies (LBGs) selected as V-band dropouts to iAB <26.3 in the Chandra Deep Field South using their rest-frame UV-to-visible spectral energy distributions. By matching the selection and performing the same analysis that has been used for z~3 samples, we show clear differences in the ensemble properties of two samples of LBGs which are separated by 1Gyr in lookback time. We find that z~5 LBGs are typically much younger (<100Myr) and have lower stellar masses (~10^9 Solar masses) than their z~3 counterparts (which are typically ~few×10^10 Solar masses and ~320Myr old). The difference in mass is significant even when considering the presence of an older, underlying population in both samples. Such young and moderately massive systems dominate the luminous z~5 LBG population (&70 per cent), whereas they comprise .30 per cent of LBG samples at z~3. This result, which we demonstrate is robust under all reasonable modelling assumptions, shows a clear change in the properties of the luminous LBGs between z~5 and z~3. These young and moderately massive z~5 LBGs appear to be experiencing their first (few) generations of large-scale star formation and are accumulating their first significant stellar mass. Their dominance in luminous LBG samples suggests that z~5 witnesses a period of wide-spread, recent galaxy formation. As such, z~5 LBGs are the likely progenitors of the spheroidal components of present-day massive galaxies.
This is supported by their high stellar mass surface densities, and is consistent with their core phase-space densities, as well as the ages of stars in the bulge of our Galaxy and other massive systems. With implied formation redshifts of z~6 - 7, these luminous z~5 LBGs could have only contributed to the UV photon budget at the end of reionisation. However, their high star formation rates per unit area suggest these systems host outflows or winds that enrich the intra- and inter-galactic media with metals, as has been established for z~3 LBGs. Their estimated young ages are consistent with inefficient metal-mixing on galaxy-wide scales. Therefore these galaxies may contain a significant fraction of metal-free stars as has been previously proposed for z~3 LBGs (Jimenez & Haiman 2006).

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