Paper detail

SPITZER observations of Abell 1763. III. The infrared luminosity function in different supercluster environments

We determine the galaxy infrared (IR) luminosity function (LF) as a function of the environment in a supercluster at z=0.23, using optical, near-IR, and mid- to far-IR photometry, as well as redshifts from optical spectroscopy. We identify 467 supercluster members in a sample of 24-micron-selected galaxies, on the basis of their spectroscopic (153) and photometric (314) redshifts. IR luminosities, stellar masses and star formation rates (SFRs) are determined for supercluster members via spectral energy distribution fitting and the Kennicutt relation. Galaxies with active galactic nuclei are excluded from the sample. We determine the IR LF of the whole supercluster as well as the IR LFs of three different regions in the supercluster: the cluster core, a large-scale filament, and the cluster outskirts (excluding the filament). The IR LF shows an environmental dependence which is not simply related to the local galaxy density. The filament, an intermediate-density region in the A1763 supercluster, contains the highest fraction of IR-emitting galaxies at all levels of IR luminosities. As expected, the core contains the lowest fraction of IR-emitting galaxies and almost no Luminous IR Galaxies (LIRGs). The relation between galaxy specific SFRs and stellar masses does not depend on the environment, and it indicates that most supercluster LIRGs (in particular those in the filament) are rather massive galaxies with relatively low specific SFRs. A comparison with previous IR LF determinations from the literature confirms that the mass-normalized total SFR in clusters increases with redshift, but more rapidly than previously suggested for redshifts <0.4. We interpret our findings within a possible scenario for the evolution of galaxies in and around clusters [Abridged].