Galaxy Bias and its Effects on the Baryon Acoustic Oscillations Measurements

TL;DR

This study uses high-resolution simulations to examine how galaxy bias affects BAO measurements, finding that bias can cause shifts in the acoustic scale but reconstruction techniques effectively mitigate these effects.

Contribution

The paper demonstrates that galaxy bias impacts BAO scale measurements and shows that reconstruction methods can reduce these biases to improve accuracy.

Findings

Bias with b<3 does not significantly shift the BAO scale.

High bias models (b>3) show measurable shifts in the BAO scale.

Reconstruction reduces shifts, aligning galaxy bias results with dark matter measurements.

Abstract

The baryon acoustic oscillation (BAO) feature in the clustering of matter in the universe serves as a robust standard ruler and hence can be used to map the expansion history of the universe. We use high force resolution simulations to analyze the effects of galaxy bias on the measurements of the BAO signal. We apply a variety of Halo Occupation Distributions (HODs) and produce biased mass tracers to mimic different galaxy populations. We investigate whether galaxy bias changes the non-linear shifts on the acoustic scale relative to the underlying dark matter distribution presented by Seo et al (2009). For the less biased HOD models (b < 3), we do not detect any shift in the acoustic scale relative to the no-bias case, typically 0.10% \pm 0.10%. However, the most biased HOD models (b > 3) show a shift at moderate significance (0.79% \pm 0.31% for the most extreme case). We test the one-step reconstruction technique introduced by Eisenstein et al. (2007) in the case of realistic galaxy bias and shot noise. The reconstruction scheme increases the correlation between the initial and final (z = 1) density fields achieving an equivalent level of correlation at nearly twice the wavenumber after reconstruction. Reconstruction reduces the shifts and errors on the shifts. We find that after reconstruction the shifts from the galaxy cases and the dark matter case are consistent with each other and with no shift. The 1-sigma systematic errors on the distance measurements inferred from our BAO measurements with various HODs after reconstruction are about 0.07% - 0.15%.