Mass-Dependent Baryon Acoustic Oscillation Signal and Halo Bias

Abstract

We characterize the baryon acoustic oscillations (BAO) feature in halo two-point statistics using N-body simulations. We find that nonlinear damping of the BAO signal is less severe for halos in the mass range we investigate than for dark matter. The amount of damping depends weakly on the halo mass. The correlation functions show a mass-dependent drop of the halo clustering bias below roughly 90 Mpc/h, which coincides with the scale of the BAO trough. The drop of bias is 4% for halos with mass M>1014 Msun/h and reduces to roughly 2% for halos with mass M>1013 Msun/h. In contrast, halo biases in simulations without BAO change more smoothly around 90 Mpc/h. In Fourier space, the bias of M>1014 Msun/h halos decreases smoothly by 11% from wavenumber k = 0.012 h/Mpc to 0.2 h/Mpc, whereas that of M>1013 Msun/h halos decreases by less than 4% over the same range. By comparing the halo biases in pairs of otherwise identical simulations, one with and the other without BAO, we also observe a modulation of the halo bias. These results suggest that precise calibrations of the mass-dependent BAO signal and scale-dependent bias on large scales would be needed for interpreting precise measurements of the two-point statistics of clusters or massive galaxies in the future.