The Imperial IRAS-FSC Redshift Catalogue: luminosity functions, evolution and galaxy bias

TL;DR

This paper analyzes the luminosity functions, evolution, and galaxy bias of 60 micron galaxies from the Imperial IRAS-FSC Redshift Catalogue, revealing different evolutionary trends among galaxy types and linking star formation rates to galaxy clustering.

Contribution

It provides the first detailed luminosity function and evolution analysis for this galaxy sample, including galaxy bias and clustering dependence on star formation activity.

Findings

Detected density and luminosity evolution consistent with previous studies.

Different galaxy types exhibit distinct evolutionary trends.

Star-forming galaxies with higher SFR show stronger clustering.

Abstract

We present the luminosity function and selection function of 60 micron galaxies selected from the Imperial IRAS-FSC Redshift Catalogue (IIFSCz). Three methods, including the 1/Vmax} and the parametric and non-parametric maximum likelihood estimator, are used and results agree well with each other. A density evolution proportional to (1+z)^3.4 or a luminosity evolution exp(1.7 t_L / \tau)$ where t_L is the look-back time is detected in the full sample in the redshift range [0.02, 0.1], consistent with previous analyses. Of the four infrared subpopulations, cirrus-type galaxies and M82-type starbursts show similar evolutionary trends, galaxies with significant AGN contributions show stronger positive evolution and Arp 220-type starbursts exhibit strong negative evolution. The dominant subpopulation changes from cirrus-type galaxies to M82-type starbursts at log (L_60 / L_Sun) ~ 10.3. In the second half of the paper, we derive the projected two-point spatial correlation function for galaxies of different infrared template type. The mean relative bias between cirrus-type galaxies and M82-type starbursts, which correspond to quiescent galaxies with optically thin interstellar dust and actively star-forming galaxies respectively, is calculated to be around 1.25. The relation between current star formation rate (SFR) in star-forming galaxies and environment is investigated by looking at the the dependence of clustering on infrared luminosity. We found that M82-type actively star-forming galaxies show stronger clustering as infrared luminosity / SFR increases. The correlation between clustering strength and SFR in the local Universe seems to echo the basic trend seen in star-forming galaxies in the Great Observatories Origins Deep Survey (GOODS) fields at z ~ 1.