Calibrating redshift distributions at z>2 with Lyman-α forest cross-correlations

Abstract

We explore the feasibility of using Lyman-α (Lyα) forests to calibrate the ensemble redshift distribution of the high-redshift tail (2<z<3) of photometric galaxies. We use CoLoRe simulations to create mock DESI 5-year Lyα forests and Rubin Observatory LSST 10-year photometric galaxies up to z=3, and measure the galaxy redshift distribution via their angular cross-correlations. Due to large redshift-space distortions in the Lyα forest, the conventional n(z) estimator for clustering redshifts does not apply, and we develope a theoretical framework to model the angular cross-correlation directly. Using the simulations, we explore effects of instrumental noise, continuum fitting, and contamination in the Lyα forest, cross-correlation angular scales (θ), and redshift bin size ( z) on the signal-to-noise (SNR) of the measurements. We find that continuum fitting methods strongly impact the SNR of the measurements. With our baseline continuum fitting method, LyCAN, at angular scales θ10 arcmin and z=0.1, we measure the cross-correlation signal at 24σ. If the shape of the redshift distribution and galaxy bias evolution are known well for z<2, the cross-correlation can constrain the mean redshift of the galaxy sample to σz/(1+z) = 0.006 at a mean redshift of z=2. This demonstrates that Lyα cross-correlation is a reliable and promising method to calibrate the high-redshift tails of photometric Stage IV galaxy surveys.