Measurement of Galaxy Clustering at z~7.2 and the Evolution of Galaxy Bias from 3.8<z<8 in the XDF, GOODS-S AND GOODS-N

Abstract

Lyman-Break Galaxy (LBG) samples observed during reionization (z6) with Hubble Space Telescope's Wide Field Camera 3 are reaching sizes sufficient to characterize their clustering properties. Using a combined catalog from the Hubble eXtreme Deep Field and CANDELS surveys, containing N=743 LBG candidates at z>6.5 at a mean redshift of z=7.2, we detect a clear clustering signal in the angular correlation function (ACF) at 4σ, corresponding to a real-space correlation length r0=6.7+0.9-1.0h-1cMpc. The derived galaxy bias b=8.6+0.9-1.0 is that of dark-matter halos of M=1011.1+0.2-0.3M at z=7.2, and highlights that galaxies below the current detection limit (MAB-17.7) are expected in lower-mass halos (M108-1010.5M). We compute the ACF of LBGs at z3.8-z5.9 in the same surveys. A trend of increasing bias is found from z=3.8 (b3.0) to z=7.2 (b8.6), broadly consistent with galaxies at fixed luminosity being hosted in dark-matter halos of similar mass at 4<z<6, followed by a slight rise in halo masses at z7 (2σ confidence). Separating the data at the median luminosity of the z=7.2 sample (MUV=-19.4) shows higher clustering at z=5.9 for bright galaxies (r0=5.5+1.4-1.5h-1cMpc, b=6.2+1.2-1.5) compared to faint galaxies (r0=1.9+1.1-1.0h-1cMpc, b=2.71.2) implying a constant mass-to-light ratio dlogMdlogL1.2+1.8-0.8. A similar trend is present in the z=7.2 sample with larger uncertainty. Finally, our bias measurements allow us to investigate the fraction of dark-matter halos hosting UV-bright galaxies (the duty-cycle, εDC). At z=7.2 values near unity are preferred, which may be explained by the shortened halo assembly time at high-redshift.