Cosmology beyond BAO from the 3D distribution of the Lyman-α forest

Abstract

We propose a new method for fitting the full-shape of the Lyman-α (Lyα) forest three-dimensional (3D) correlation function in order to measure the Alcock-Paczynski (AP) effect. Our method preserves the robustness of baryon acoustic oscillations (BAO) analyses, while also providing extra cosmological information from a broader range of scales. We compute idealized forecasts for the Dark Energy Spectroscopic Instrument (DESI) using the Lyα auto-correlation and its cross-correlation with quasars, and show how this type of analysis improves cosmological constraints. The DESI Lyα BAO analysis is expected to measure H(zeff)rd and DM(zeff)/rd with a precision of 0.9\% each, where H is the Hubble parameter, rd is the comoving BAO scale, DM is the comoving angular diameter distance and the effective redshift of the measurement is zeff2.3. By fitting the AP parameter from the full shape of the two correlations, we show that we can obtain a precision of 0.5-0.6\% on each of H(zeff)rd and DM(zeff)/rd. Furthermore, we show that a joint full-shape analysis of the Lyα auto-correlation and its cross-correlation with quasars can measure the linear growth rate times the amplitude of matter fluctuations in spheres of 8\;h-1Mpc, fσ8(zeff). Such an analysis could provide the first ever measurement of fσ8(zeff) at redshift zeff>2. By combining this with the quasar auto-correlation in a joint analysis of the three high-redshift two-point correlation functions, we show that DESI could be able to measure fσ8(zeff2.3) with a precision of 5-12\%, depending on the smallest scale fitted.