Dark Energy Survey Year 1 Results: Measurement of the Galaxy Angular Power Spectrum

TL;DR

This paper measures the galaxy angular power spectrum from DES Year 1 data, detects the BAO feature with moderate significance, and provides cosmological distance constraints consistent with previous DES results.

Contribution

It introduces a novel harmonic space analysis method for BAO detection in DES Y1 data, validated with mock catalogs and applied to real data for cosmological measurements.

Findings

BAO feature detected at 2.6 sigma significance

Distance measurement D_A(z)/r_d = 10.65 ± 0.49

Method validated with mock catalogs and improved covariance modeling

Abstract

We use data from the first-year (Y1) observations of the DES collaboration to measure the galaxy angular power spectrum (APS), and search for its BAO feature using a template-fitting method. We test our methodology in a sample of 1800 DES Y1-like mock catalogs. The APS is measured with the pseudo-$C_\ell$ method, using pixelized maps constructed from the mock catalogs and the DES mask. The covariance matrix of the $C_\ell$'s in these tests are also obtained from the mock catalogs. We use templates to model the measured spectra and estimate template parameters firstly from the $C_\ell$'s of the mocks using two different methods, a maximum likelihood estimator and a MCMC, finding consistent results with a good reduced $\chi^2$. Robustness tests are performed to estimate the impact of different choices of settings used in our analysis. After these tests on mocks, we apply our method to a galaxy sample constructed from DES Y1 data specifically for LSS studies. This catalog comprises galaxies within an effective area of 1318 deg$^2$ and $0.6<z<1.0$. We fit the observed spectra with our optimized templates, considering models with and without BAO features. We find that the DES Y1 data favors a model with BAO at the $2.6\,\sigma$ C.L. with a best-fit shift parameter of $\alpha=1.023\pm 0.047$. However, the goodness-of-fit is somewhat poor, with $\chi^2/$(dof) = 1.49. We identify a possible cause of this issue and show that using a theoretical covariance matrix obtained from $C_\ell$'s that are better adjusted to data results in an improved value of $\chi^2/$(dof) = 1.36 which is similar to the value obtained with the real-space analysis. Our results correspond to a distance measurement of $D_A(z_{\rm eff} = 0.81)/r_d = 10.65 \pm 0.49$, consistent with the main DES BAO findings. This is a companion paper to the main DES BAO article showing the details of the harmonic space analysis.