FLAMINGO: The thermal history of the Universe from tSZ effect cross-correlations and its dependencies on cosmology and baryon physics

Abstract

The cross-correlation between tracers of large-scale structure, such as galaxies or quasars, and the thermal Sunyaev-Zel'dovich (tSZ) signal yields a measure of the bias-weighted mean electron pressure, bh Pe , where bh is the halo bias and Pe is the electron pressure. With a model for the bias, one can derive the thermal history, dy/dz, where y is the Compton parameter and z is redshift. We explore how these quantities depend on redshift, cosmology, and the physics of galaxy formation using the FLAMINGO suite of cosmological hydrodynamical simulations, which spans a range of cosmological parameters and baryonic feedback implementations in volumes of up to (2.8\,Gpc)3. We find that bh Pe depends steeply on S8 σ8Ωm/0.3, with an effective scaling bh Pe S8ε(z), where the exponent ε(z) ≈ 3 over the redshift range 0.1 ≤ z ≤ 1. Compared with existing cross-correlation measurements using tracer samples from SDSS, BOSS, eBOSS, DES, and DESI cross-correlated with tSZ measurements from Planck, we find that models with a low-S8 cosmology and strong feedback are preferred, with a joint fit yielding S8 = 0.72+0.03-0.03 and a normalised group-mass halo baryon fraction fb(1013\,M, z=0.1)/(Ωb/Ωm) = 0.10+0.09-0.05 . Contrary to most probes of feedback which sample smaller scales (e.g., X-ray measurements), we show that feedback boosts bh Pe , thus providing a novel test of feedback models. Overall, our results show the thermal history provides a route to jointly constrain cosmological parameters and test models of galaxy formation.