Constraining reionization with the first measurement of the cross-correlation between the CMB optical-depth fluctuations and the Compton y-map

Abstract

We propose a new reionization probe that uses cosmic microwave background (CMB) observations; the cross-correlation between fluctuations in the CMB optical depth which probes the integrated electron density, δτ, and the Compton y-map which probes the integrated electron pressure. This cross-correlation is much less contaminated than the y-map power spectrum by late-time cluster contributions. In addition, this cross-correlation can constrain the temperature of ionized bubbles while the optical-depth fluctuations and kinetic SZ effect can not. We measure this new observable using a Planck y-map as well as a map of optical-depth fluctuations that we reconstruct from Planck CMB temperature data. We use our measurements to derive a first CMB-only upper limit on the temperature inside ionized bubbles, T b 7.0×105\,K (2\,σ). We also present future forecasts, assuming a fiducial model with characteristic reionization bubble size R b=5\,Mpc and T b=5×104\,K. The signal-to-noise ratio of the fiducial cross-correlation using a signal dominated PICO-like y-map becomes 7 with CMB-S4 δτ and 13 with CMB-HD δτ. For the fiducial model, we predict that the CMB-HD - PICO cross-correlation should achieve an accurate measurement of the reionization parameters; T b 49800+4500-5100\,K and R b 5.09+0.66-0.79\,Mpc. Since the power spectrum of the electron density fluctuations is constrained by the δτ auto spectrum, the temperature constraints should be only weakly model-dependent on the details of the electron distributions and should be statistically representative of the temperature in ionized bubbles during reionization. This cross-correlation could, therefore, become an important observable for future CMB experiments.