Cosmology

RX J0152.7−1357: Stellar Populations in an X-Ray Luminous Galaxy Cluster at z = 0.83

The Astronomical Journal American Astronomical Society 129:3 (2005) 1249-1286

Authors:

Inger Jørgensen, Marcel Bergmann, Roger Davies, Jordi Barr, Marianne Takamiya, David Crampton

The discovery of a type II quasar at z= 1.65 with integral-field spectroscopy

\mnras 358 (2005) L11-L15-L11-L15

Authors:

MJ Jarvis, C van Breukelen, RJ Wilman

GALICS -- VI. Modelling Hierarchical Galaxy Formation in Clusters

ArXiv astro-ph/0502490 (2005)

Authors:

B Lanzoni, B Guiderdoni, GA Mamon, J Devriendt, S Hatton

Abstract:

High-resolution N-body re-simulations of 15 massive (10^{14}-10^{15} Msun) dark matter haloes have been combined with the hybrid galaxy formation model GalICS (Hatton et al. 2003), to study the formation and evolution of galaxies in clusters, within the framework of the hierarchical merging scenario. New features in GalICS include a better description of galaxy positioning within dark matter haloes, a more reliable computation of the temperature of the inter-galactic medium as a function of redshift, and a description of the ram pressure stripping process. We focus on the luminosity functions, morphological fractions and colour distributions of galaxies in clusters and in cluster outskirts, at z=0. No systematic dependency on cluster richness is found either for the galaxy luminosity functions, morphological mixes, or colour distributions. Moving from higher density (cluster cores), to lower density environments (cluster outskirts), we detect a progressive flattening of the luminosity functions, an increase of the fraction of spirals and a decrease of that of ellipticals and S0s, and the progressive emergence of a bluer tail in the distributions of galaxy colours, especially for spirals. As compared to cluster spirals, early-type galaxies show a flatter luminosity function, and more homogeneous and redder colours. An overall good agreement is found between our results and the observations, particularly in terms of the cluster luminosity functions and morphological mixes. However, some discrepancies are also apparent, with too faint magnitudes of the brightest cluster members, especially in the B band, and galaxy colours tendentially too red (or not blue enough) in the model, with respect to the observations. Finally, ram pressure stripping appears to affect very little our results.

GALICS -- VI. Modelling Hierarchical Galaxy Formation in Clusters

(2005)

Authors:

B Lanzoni, B Guiderdoni, GA Mamon, J Devriendt, S Hatton

On Statistical Lensing and the Anti-Correlation Between 2dF QSOs and Foreground Galaxies

ArXiv astro-ph/0502481 (2005)

Authors:

AD Myers, PJ Outram, T Shanks, BJ Boyle, SM Croom, NS Loaring, L Miller, RJ Smith

Abstract:

We cross-correlate APM and SDSS galaxies with background QSOs from the 2dF QSO Redshift Survey, and detect a significant (2.8sigma) anti-correlation. The lack of a signal between 2dF stars and our galaxy samples suggests the anti-correlation is not due to a systematic error. The possibility that dust in the foreground galaxies could produce the anti-correlation is marginally rejected, at the 2sigma level through consideration of QSO colours. It is possible that dust that obscures QSOs without reddening them, or preferentially discards reddened QSOs from the 2QZ sample, could produce such an anti-correlation, however, such models are at odds with the positive QSO-galaxy correlations found at bright magnitudes by other authors. Our detection of a galaxy-QSO anti-correlation is consistent with statistical lensing theory. When combined with earlier results that have reported a positive galaxy-QSO correlation, a consistent, compelling picture emerges that spans faint and bright QSO samples showing positive or negative correlations according to the QSO N(m) slope. We find that galaxies are highly anti-biased on small scales. We consider two models that use different descriptions of the lensing matter and find they yield consistent predictions for the strength of galaxy bias on 0.1Mpc/h scales of b~0.1 (for LCDM). Whilst the slope of our power-law fit to the QSO-galaxy cross-correlation does not rule out linear bias, when we compare our measurement of b on 100 kpc/h scales to independent methods that determine b~1 on Mpc/h scales, we conclude that bias, on these small scales, is scale-dependent. These results indicate more mass, at least on the 100 kpc/h scales probed, than predicted by simple LCDM biasing prescriptions, and can thus constrain halo occupation models of the galaxy distribution.