An OVI Baryon Census of the Low-z Warm-Hot Intergalactic Medium

TL;DR

This study uses FUSE data to quantify the distribution and baryonic content of OVI-bearing warm-hot intergalactic medium at low redshift, revealing a significant fraction of missing baryons in this phase.

Contribution

It provides the first large statistical survey of OVI absorbers at low redshift, improving detection counts and redshift coverage, and estimates the baryonic mass fraction in the WHIM.

Findings

At least 4.8% of baryons are in the hot WHIM phase.

The OVI column density distribution follows a steep power law, indicating many weak absorbers.

The total baryonic mass in the OVI-traced WHIM could be as high as 10%.

Abstract

Intergalactic absorbers along lines of sight to distant quasars are a powerful diagnostic for the evolution and content of the intergalactic medium (IGM). In this study, we use the FUSE satellite to search 129 known lya absorption systems at z<0.15 toward 31 AGN for corresponding absorption from higher Lyman lines and the important metal ions OVI. We detect OVI in 40 systems over a smaller range of column density than seen in HI. The co-existence of OVI and HI suggests a multiphase IGM, with warm photoionized and hot ionized components. With improved OVI detection statistics, we find a steep distribution in OVI column density, dN(OVI)/dN_OVI N_OVI^(-2.2+-0.1), suggesting that numerous weak OVI absorbers contain baryonic mass comparable to the rare strong absorbers. The total cosmological mass fraction in this hot gas is at least Omega_WHIM=(0.0022+-0.0003. Gas in the WHIM at 10^5-6 K contributes at least 4.8+-0.9% of the total baryonic mass at z<0.15. We then combine empirical scaling relations for the observed "multiphase ratio", N_HI/N_OVI N_HI^(0.9+-0.1), and for hydrogen overdensity in cosmological simulations, N_HI delta_H^{0.7}, with the HI photoionization correction to derive the mean oxygen metallicity, Z_O (0.09 Z_sun)(f_OVI/0.2)^(-1) in the low-z multiphase gas. Given the spread in the empirical relations and in f_OVI, the baryon content in the OVI WHIM could be as large as 10%. Our survey is based on a large improvement in the number of OVI absorbers (40 vs. 10) and total redshift pathlength (dz 2.2 vs. dz 0.5) compared to earlier surveys.