Understanding large-scale structure in the SSA22 protocluster region using cosmological simulations

Abstract

We investigate the nature and evolution of large-scale structure within the SSA22 protocluster region at z=3.09 using cosmological simulations. A redshift histogram constructed from current spectroscopic observations of the SSA22 protocluster reveals two separate peaks at z = 3.065 (blue) and z = 3.095 (red). Based on these data, we report updated overdensity and mass calculations for the SSA22 protocluster. We find δb,gal=4.8 1.8, δr,gal=9.5 2.0 for the blue and red peaks, respectively, and δt,gal=7.6 1.4 for the entire region. These overdensities correspond to masses of Mb = (0.76 0.17) × 1015 h-1 M, Mr = (2.15 0.32) × 1015 h-1 M, and Mt=(3.19 0.40) × 1015 h-1 M for the red, blue, and total peaks, respectively. We use the Small MultiDark Planck (SMDPL) simulation to identify comparably massive z 3 protoclusters, and uncover the underlying structure and ultimate fate of the SSA22 protocluster. For this analysis, we construct mock redshift histograms for each simulated z 3 protocluster, quantitatively comparing them with the observed SSA22 data. We find that the observed double-peaked structure in the SSA22 redshift histogram corresponds not to a single coalescing cluster, but rather the proximity of a 1015h-1 M protocluster and at least one >1014 h-1 M cluster progenitor. Such associations in the SMDPL simulation are easily understood within the framework of hierarchical clustering of dark matter halos. We finally find that the opportunity to observe such a phenomenon is incredibly rare, with an occurrence rate of 7.4h3 Gpc-3.