The Clustering Evolution of Dusty Star-Forming Galaxies

Abstract

We present predictions for the clustering of galaxies selected by their emission at far infra-red (FIR) and sub-millimetre wavelengths. This includes the first predictions for the effect of clustering biases induced by the coarse angular resolution of single-dish telescopes at these wavelengths. We combine a new version of the GALFORM model of galaxy formation with a self-consistent model for calculating the absorption and re-emission of radiation by interstellar dust. Model galaxies selected at 850 μm reside in dark matter halos of mass M halo1011.5-1012 h-1 M, independent of redshift (for 0.2 z4) or flux (for 0.25 S850μ m4 mJy). At z2.5, the brightest galaxies (S850μ m>4 mJy) exhibit a correlation length of r0=5.5-0.5+0.3 h-1 Mpc, consistent with observations. We show that these galaxies have descendants with stellar masses M1011 h-1 M occupying halos spanning a broad range in mass M halo1012-1014 h-1 M. The FIR emissivity at shorter wavelengths (250, 350 and 500 μm) is also dominated by galaxies in the halo mass range M halo1011.5-1012 h-1 M, again independent of redshift (for 0.5 z5). We compare our predictions for the angular power spectrum of cosmic infra-red background anisotropies at these wavelengths with observations, finding agreement to within a factor of 2 over all scales and wavelengths, an improvement over earlier versions of the model. Simulating images at 850 μm, we show that confusion effects boost the measured angular correlation function on all scales by a factor of 4. This has important consequences, potentially leading to inferred halo masses being overestimated by an order of magnitude.