Tracing cosmic gas in filaments and halos: Low-redshift insights from the kinematic Sunyaev-Zel'dovich effect

TL;DR

This study uses CMB and galaxy survey data to detect and analyze the distribution and alignment of gas in cosmic filaments and halos at low redshift via the kSZ effect, providing insights into the cosmic web and missing baryons.

Contribution

First measurement of gas distribution and filament alignment using the kSZ effect at low redshift, comparing observations with hydrodynamical simulations.

Findings

7.2σ detection of gas density profile in monopole

4σ detection of filament alignment in quadrupole

Data shows more extended and larger anisotropic signal than simulations

Abstract

In this work, we leverage CMB data from the Atacama Cosmology Telescope (ACT) and LSS data from the imaging survey conducted by the Dark Energy Spectroscopic Instrument (DESI) to study the distribution of gas around galaxy groups at low redshift, $z \approx 0.3$, via the kinematic Sunyaev-Zel'dovich (kSZ) effect. In particular, we perform velocity-weighted stacking on the photometric Bright Galaxy Sample (BGS) to isolate the monopole and quadrupole of the kSZ signal, orienting the stacked images along 2D filaments identified using the Hessian of the projected gravitational potential. We find a 7.2$\sigma$ detection in the monopole of the signal (i.e., the gas density profile) and a 4$\sigma$ detection in the quadrupole ($m = 2$), constituting the first measurement of the alignment between gas distribution and the cosmic web through the kSZ effect. As it is a linear probe of the local gas density, the kSZ has heightened sensitivity to the warm-hot intergalactic medium (WHIM), which is believed to house the majority of the ``missing baryons.'' Mapping out the gas density at low redshifts, as enabled by our measurements, is crucial for weak lensing surveys, for which the impact of baryons on small scales is a major impediment. We compare the anisotropic signal against two hydrodynamical simulations, TNG300-1 and Illustris, which have very different baryonic feedback prescriptions. We find that the anisotropic signal measured in the data is comparable but slightly larger and more extended compared with the simulations. This suggests that there is excess accretion and feedback taking place through the filaments, hinting at the possible presence of spin-filament alignment of the BGS objects.