Reconstructing the baryon acoustic oscillations using biased tracers

TL;DR

This paper investigates how biased tracers affect nonlinear reconstruction of the initial universe conditions, demonstrating that including bias improves BAO feature recovery, especially with optimal grid resolution and mass assignment schemes.

Contribution

It adapts the Shi et al. reconstruction method to biased tracers, analyzing the impact of various factors and biases on reconstruction performance in cosmology.

Findings

Optimal grid resolution is around 1-2 h^{-1} Mpc.

Including bias significantly improves BAO recovery.

Linear bias is the most influential factor in reconstruction.

Abstract

The reconstruction of the initial conditions of the Universe is an important topic in cosmology, particularly in the context of sharpening the measurement of the baryon acoustic oscillation (BAO) peak. Nonlinear reconstruction algorithms developed in recent years, when applied to late-time matter fields, can recover to a substantial degree the initial density distribution, however, when applied to sparse tracers of the matter field, the performance is poorer. In this paper we apply the Shi et al. non-linear reconstruction method to biased tracers in order to establish what factors affect the reconstruction performance. We find that grid resolution, tracer number density and mass assignment scheme all have a significant impact on the performance of our reconstruction method, with triangular-shaped-cloud (TSC) mass assignment and a grid resolution of ${\sim}1{-}2h^{-1}$ Mpc being the optimal choice. We also show that our method can be easily adapted to include generic tracer biases up to quadratic order in the reconstruction formalism. Applying the reconstruction to halo and galaxy samples with a range of tracer number densities, we find that the linear bias is by far the most important bias term, while including nonlocal and nonlinear biases only leads to marginal improvements on the reconstruction performance. Overall, including bias in the reconstruction substantially improves the recovery of BAO wiggles, down to $k\sim0.25~h\text{Mpc}^{-1}$ for tracer number densities between $2\times10^{-4}$ and $2\times10^{-3}~(h^{-1}\text{Mpc})^{-3}$.