Absorption signatures of warm-hot gas at low redshift: Broad HI Lyman-Alpha Absorbers

TL;DR

This study uses cosmological simulations to analyze broad HI Lyman-Alpha absorbers at low redshift, revealing their origins in shock-heated, enriched gas in the warm-hot intergalactic medium and their potential as probes of feedback processes.

Contribution

It provides the first detailed simulation-based analysis of BLAs at low redshift, linking their properties to the physical state of the WHIM and feedback mechanisms.

Findings

BLAs arise mainly in warm-hot, low-density gas.

Thermal broadening accounts for at least 60% of BLA line width.

Detectable BLAs represent a small fraction of the total baryon content.

Abstract

We investigate the physical state of HI absorbing gas at low redshift (z = 0.25) using a subset of cosmological, hydrodynamic simulations from the OWLS project, focusing in particular on broad (b_HI > 40 km/s) HI Lyman-Alpha absorbers (BLAs), which are believed to originate in shock-heated gas in the warm-hot intergalactic medium (WHIM). Our fiducial model, which includes radiative cooling by heavy elements and feedback by supernovae and active galactic nuclei, predicts that by z = 0.25 nearly 60 per cent of the gas mass ends up at densities and temperatures characteristic of the WHIM and we find that half of this fraction is due to outflows. The standard HI observables (distribution of HI column densities N_HI, distribution of Doppler parameters b_HI, b_HI - N_HI correlation) and the BLA line number density predicted by our simulations are in remarkably good agreement with observations. BLAs arise in gas that is hotter, more highly ionised and more enriched than the gas giving rise to typical Lyman-Alpha forest absorbers. The majority of the BLAs arise in warm-hot (log (T/K) ~ 5) gas at low (log Delta < 1.5) overdensities. On average, thermal broadening accounts for at least 60 per cent of the BLA line width, which in turn can be used as a rough indicator of the thermal state of the gas. Detectable BLAs account for only a small fraction of the true baryon content of the WHIM at low redshift. In order to detect the bulk of the mass in this gas phase, a sensitivity at least one order of magnitude better than achieved by current ultraviolet spectrographs is required. We argue that BLAs mostly trace gas that has been shock-heated and enriched by outflows and that they therefore provide an important window on a poorly understood feedback process.