Dark Energy Survey Year 3 Results: Measurement of the Baryon Acoustic Oscillations with Three-dimensional Clustering

Abstract

The three-dimensional correlation function offers an effective way to summarize the correlation of the large-scale structure even for imaging galaxy surveys. We have applied the projected three-dimensional correlation function, p to measure the Baryonic Acoustic Oscillations (BAO) scale on the first-three years Dark Energy Survey data. The sample consists of about 7 million galaxies in the redshift range 0.6 < z p < 1.1 over a footprint of 4108 \, deg2 . Our theory modeling includes the impact of realistic true redshift distributions beyond Gaussian photo-z approximation. To increase the signal-to-noise of the measurements, a Gaussian stacking window function is adopted in place of the commonly used top-hat. Using the full sample, D M(z eff ) / r s , the ratio between the comoving angular diameter distance and the sound horizon, is constrained to be 19.00 0.67 (top-hat) and 19.15 0.58 (Gaussian) at z eff = 0.835. The constraint is weaker than the angular correlation w constraint (18.84 0.50) because the BAO signals are heterogeneous across redshift. When a homogeneous BAO-signal sub-sample in the range 0.7 < z p < 1.0 (z eff = 0.845) is considered, p yields 19.80 0.67 (top-hat) and 19.84 0.53 (Gaussian). The latter is mildly stronger than the w constraint (19.86 0.55 ). We find that the p results are more sensitive to photo-z errors than w because p keeps the three-dimensional clustering information causing it to be more prone to photo-z noise. The Gaussian window gives more robust results than the top-hat as the former is designed to suppress the low signal modes. p and the angular statistics such as w have their own pros and cons, and they serve an important crosscheck with each other.