Role of ionizing background on the statistics of metal absorbers in hydrodynamical simulations

TL;DR

This study investigates how the ionizing background affects the statistical properties of metal absorbers in low-redshift hydrodynamical simulations, highlighting the importance of UVB variations and feedback processes.

Contribution

It demonstrates the influence of different UV backgrounds and feedback models on metal absorber statistics, emphasizing the need for combined analysis of multiple observables.

Findings

UVB significantly impacts absorber distribution functions.

Simulations with combined wind and AGN feedback match some observed properties.

Different UVB models produce variations comparable to changing feedback parameters.

Abstract

We study the statistical properties of O VI, C IV, and Ne VIII absorbers at low-$z$ (i.e., $z<0.5$) using Sherwood simulations with "WIND" only and "WIND+AGN" feedback and Massive black simulation that incorporates both "WIND" i.e. outflows driven by stellar feedback and AGN feedbacks. For each simulation, by considering a wide range of metagalactic ionizing UV background (UVB), we show the statistical properties such as distribution functions of column density ($N$), $b$-paramerer and velocity spread ($\Delta V_{90}$), the relationship between $N$ and $b$-parameter and the fraction of Lya absorbers showing detectable metal lines as a function of $N$(H I) are influenced by the UVB used. This is because UVB changes the range in density, temperature, and metallicity of gas contributing to a given absorption line. For simulations considered here, we show the difference in some of the predicted distributions between different simulations is similar to the one obtained by varying the UVB for a given simulation. Most of the observed properties of O VI absorbers are roughly matched by Sherwood simulation with "WIND+AGN" feedback when using the UVB with a lower O VI ionization rate. However, this simulation fails to produce observed distributions of C IV and fraction of H I absorbers with detectable metals. Therefore, in order to constrain different feedback processes and/or UVBs, using observed properties of H I and metal ions, it is important to perform simultaneous analysis of various observable parameters.