SZ effects in the Magneticum Pathfinder Simulation: Comparison with the Planck, SPT, and ACT results

TL;DR

This paper uses advanced cosmological hydrodynamical simulations to analyze the Sunyaev-Zeldovich effects, comparing the results with Planck, SPT, and ACT observations, and investigates the consistency of the simulated signals with observational data.

Contribution

It presents detailed predictions of SZ effects from the Magneticum Pathfinder simulations and compares them with observational data, highlighting agreements and discrepancies.

Findings

The tSZ power spectrum matches Planck data up to l~1000.

The simulated mean Compton Y parameter aligns with Planck estimates.

The tSZ power spectrum at l=3000 exceeds ground-based measurements.

Abstract

We calculate the one-point probability density distribution functions (PDF) and the power spectra of the thermal and kinetic Sunyaev-Zeldovich (tSZ and kSZ) effects and the mean Compton Y parameter using the Magneticum Pathfinder simulations, state-of-the-art cosmological hydrodynamical simulations of a large cosmological volume of (896 Mpc/h)^3. These simulations follow in detail the thermal and chemical evolution of the intracluster medium as well as the evolution of super-massive black holes and their associated feedback processes. We construct full-sky maps of tSZ and kSZ from the light-cones out to z=0.17, and one realization of 8.8x8.8 degree wide, deep light-cone out to z=5.2. The local universe at z<0.027 is simulated by a constrained realisation. The tail of the one-point PDF of tSZ from the deep light-cone follows a power-law shape with an index of -3.2. Once convolved with the effective beam of Planck, it agrees with the PDF measured by Planck. The predicted tSZ power spectrum agrees with that of the Planck data at all multipoles up to l~1000, once the calculations are scaled to the Planck 2015 cosmological parameters with \Omega_m=0.308 and \sigma_8=0.8149. Consistent with the results in the literature, however, we continue to find the tSZ power spectrum at l=3000 that is significantly larger than that estimated from the high-resolution ground-based data. The simulation predicts the mean fluctuating Compton Y value of <Y>=1.18x10^{-6} for \Omega_m=0.272 and \sigma_8=0.809. Nearly half (~ 5x10^{-7}) of the signal comes from halos below a virial mass of 10^{13}M_\odot/h. Scaling this to the Planck 2015 parameters, we find <Y>=1.57x10^{-6}. The PDF and the power spectrum of kSZ from our simulation agree broadly with the previous work.