Measurement of angular cross-correlation between the cosmological dispersion measure and the thermal Sunyaev--Zeldovich effect

Abstract

The dispersion measures ( DMs) from fast radio bursts (FRBs) and the thermal Sunyaev--Zeldovich (tSZ) effect probe the free-electron density and thermal pressure, respectively, in the intergalactic medium (IGM) and the intervening galaxies and clusters. Their combination enables disentangling the gas density and temperature. In this work, we present the first detection of an angular cross-correlation between the DMs and the Compton y parameter of the tSZ effect. The theoretical expectation is calculated using the halo model HMx, calibrated with hydrodynamic simulations. The observational cross-correlation is measured over angular separations of 1--1000 using the DMs from 133 localized FRBs and the y-maps from the Planck satellite and the Atacama Cosmology Telescope (ACT). We detect a positive correlation with amplitudes of A=2.01 0.50 (4.0 σ) for Planck and A=1.23 0.82 (1.5 σ) for ACT, where A=1 corresponds to the theoretical prediction of the Planck 2018 ΛCDM cosmology. Assuming an isothermal gas, the measured amplitude implies an average electron temperature of ≈ 2 × 107 \, K. The correlation is highly sensitive to the matter clustering parameter σ8 and to baryon feedback, and its dependence on other cosmological and astrophysical parameters -- such as the ionized fraction and the Hubble constant -- differs from that of the DM alone. This suggests that future joint analyses of the DMs and the tSZ effect could help break degeneracies among these parameters.