Sunyaev-Zeldovich Signals from L* Galaxies: Observations, Analytics, and Simulations

Abstract

We analyze measurements of the thermal Sunyaev-Zeldovich (tSZ) effect arising in the circumgalactic medium (CGM) of L* galaxies, reported by Bregman et al. 2022 and Das et al. 2023. In our analysis we use the Faerman et al. 2017 and Faerman et al. 2020 CGM models, a new power-law model (PLM), and the TNG100 simulation. For a given M vir, our PLM has four parameters; the fraction, f hCGM, of the halo baryon mass in hot CGM gas, the ratio, φT, of the actual gas temperature at the virial radius to the virial temperature, and the power-law indicies, aP, th and an for the thermal electron pressure and the hydrogen nucleon density. The B+22 Compton-y profile implies steep electron pressure slopes (aP, th 2). For isothermal conditions the temperature is at least 1.1× 106 K, with a hot CGM gas mass of up to 3.5× 1011 M for a virial mass of 2.75× 1012 M. However, if isothermal the gas must be expanding out of the halos. An isentropic equation of state is favored for which hydrostatic equilibrium is possible. The B+22 and D+23 results are consistent with each other and with recent (0.5-2 keV) CGM X-ray observations by Zhang et al. 2024 of Milky Way mass systems. For M vir 3× 1012 M, the scaled Compton pressure integrals, E(z)-2/3Y500/M vir,125/3, lie in the narrow range, 2.5× 10-4 to 5.0× 10-4 kpc2, for all three sets of observations. TNG100 underpredicts the tSZ parameters by factors 0.5 dex for the L* galaxies, suggesting that the feedback strengths and CGM gas losses are overestimated in the simulated halos at these mass scales.