Tracing the 10$^7$K Warm-Hot Intergalactic Medium with UV absorption lines

TL;DR

This study investigates the hot, 10^7 K intergalactic gas believed to contain missing baryons by using UV absorption lines, providing a ground-based alternative to X-ray detection methods.

Contribution

It introduces a novel UV absorption line approach to trace the 10^7 K warm-hot intergalactic medium, offering a potentially more accessible detection method.

Findings

Stacking quasar spectra sets a 5-sigma upper limit on Fe XXI column density.

Current observations are three orders of magnitude above expected WHIM levels.

Future facilities may enable detection of the missing baryons through this UV method.

Abstract

Today, the majority of the cosmic baryons in the Universe are not observed directly, leading to an issue of "missing baryons" at low redshift. Cosmological hydrodynamical simulations have indicated that a significant portion of them will be converted into the so-called Warm-Hot Intergalactic Medium (WHIM), with gas temperature ranging between 10$^5$-10$^7$K. While the cooler phase of this gas has been observed using O VI and Ne VIII absorbers at UV wavelengths, the hotter fraction detection relies mostly on observations of O VII and O VIII at X-ray wavelengths. Here, we target the forbidden line of [Fe XXI] $\lambda$ 1354$\unicode{x212B}$ which traces 10$^7$K gas at UV wavelengths, using more than one hundred high-spectral resolution (R$\sim$49,000) and high signal to noise VLT/UVES quasar spectra, corresponding to over 600 hrs of VLT time observations. A stack of these at the position of known DLAs lead to a 5-$\sigma$ limit of $\mathrm{log[N([Fe\,XXI])]<}$17.4 (${EW_{rest}<22}$m$\unicode{x212B}$), three orders of magnitude higher than the expected column density of the WHIM $\mathrm{log[N([Fe\,XXI])]<}$14.5. This work proposes an alternative to X-ray detected 10$^7$K WHIM tracers, by targeting faint lines at UV wavelengths from the ground benefiting from higher instrumental throughput, enhanced spectral resolution, longer exposure times and increased number of targets. The number of quasar spectra required to reach this theoretical column density with future facilities including 4MOST, ELT/HIRES, MSE and the Spectroscopic Telescope appears challenging at present. Probing the missing baryons is essential to constrain the accretion and feedback processes which are fundamental to galaxy formation.