Near-infrared and optical luminosity functions from the 6dF Galaxy Survey

Authors

Errata

This article is corrected by:

  1. Errata: Erratum: Near-infrared and optical luminosity functions from the 6dF Galaxy Survey Volume 370, Issue 3, 1583–1584, Article first published online: 5 July 2006

★ E-mail: heath@aao.gov.au (DHJ); peterson@mso.anu.edu.au (BAP); colless@aao.gov.au (MC); will@aao.gov.au (WS)

ABSTRACT

Luminosity functions and their integrated luminosity densities are presented for the 6-degree Field Galaxy Survey (6dFGS). This ongoing survey ultimately aims to measure around 150 000 redshifts and 15 000 peculiar velocities over almost the entire southern sky at |b| > 10°. The main target samples are taken from the 2-Micron All-Sky Survey (2MASS) Extended Source Catalog and the SuperCOSMOS Sky Survey catalogue, and comprise 138 226 galaxies complete to (K, H, J, rF, bJ) = (12.75, 13.00, 13.75, 15.60, 16.75). These samples are comparable in size to the optically selected Sloan Digital Sky Survey and 2-degree Field Galaxy Redshift Survey (2dFGRS) samples, and improve on recent near-infrared-selected redshift surveys by more than an order of magnitude in both number and sky coverage. The partial samples used in this paper contain a little over half of the total sample in each band and are ∼90 per cent complete.

Luminosity distributions are derived using the 1/Vmax, Sandage–Tammann–Yahil (STY) and step-wise maximum likelihood (SWML) estimators, and probe 1–2 absolute magnitudes fainter in the near-infrared than previous surveys. The effects of magnitude errors, redshift incompleteness and peculiar velocities have been taken into account and corrected throughout. Generally, the 6dFGS luminosity functions are in excellent agreement with those of similarly sized surveys. Our data are of sufficient quality to demonstrate that a Schechter function is not an ideal fit to the true luminosity distribution, due to its inability to simultaneously match the faint-end slope and rapid bright-end decline. Integrated luminosity densities from the 6dFGS are consistent with an old stellar population and moderately declining star formation rate.

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