The clustering and evolution of H-alpha emitters at z~1 from HiZELS

Abstract

(Abridged) The clustering properties of a well-defined sample of 734 H-alpha emitters at z=0.84 obtained as part of the Hi-z Emission Line Survey (HiZELS) are investigated. The spatial correlation function is very well-described by (r/r0)-1.8, with r0=2.7+-0.3Mpc/h. The correlation length r0 increases strongly with H-alpha luminosity, LH-alpha, from r0~2Mpc/h for the most quiescent galaxies (star-formation rates of ~4Msun/yr), up to r0>5Mpc/h for the brightest galaxies in H-alpha. The correlation length also increases with increasing rest-frame K-band luminosity (MK), but the r0-LH-alpha correlation maintains its full statistical significance at fixed MK. At z=0.84, star-forming galaxies classified as irregulars or mergers are much more clustered than discs and non-mergers, but once the samples are matched in LH-alpha and MK, the differences vanish, implying that the clustering is independent of morphological type at z~1. The typical H-alpha emitters found at z=0.84 reside in dark-matter haloes of ~1012Msun, but those with the highest SFRs reside in more massive haloes of ~1013Msun. Comparing the results with those of H-alpha surveys at different redshifts, it is seen that although the break of the H-alpha luminosity function, L*, evolves by a factor of ~30 from z=0.24 to z=2.23, galaxies with the same LH-alpha/L*(z) are found in dark matter haloes of similar masses, independently of cosmic time. This not only confirms that star-formation is more efficient at higher redshift, but also suggests a fundamental connection between the strong decrease of L* since z=2.23 and the quenching of star-formation in galaxies residing within dark-matter haloes significantly more massive than 1012Msun at any given epoch.