# Relationship between the Metallicity of the Circumgalactic Medium and   Galaxy Orientation

**Authors:** Stephanie K. Pointon, Glenn G. Kacprzak, Nikole M. Nielsen, Sowgat, Muzahid, Michael T. Murphy, Christopher W. Churchill, Jane C. Charlton

arXiv: 1907.05557 · 2019-10-02

## TL;DR

This study examines the metallicity distribution in the circumgalactic medium of 47 low-redshift galaxies, finding it to be largely independent of galaxy orientation and halo mass, with implications for gas accretion and outflow processes.

## Contribution

It provides the first detailed analysis of CGM metallicity distribution relative to galaxy orientation, revealing independence from azimuthal and inclination angles at low redshift.

## Key findings

- Metallicity distribution appears bimodal but may be unimodal.
- CGM metallicity is independent of halo mass.
- No dependence of metallicity on galaxy azimuthal or inclination angles.

## Abstract

We investigate the geometric distribution of gas metallicities in the circumgalactic medium (CGM) around $47$, $z<0.7$ galaxies from the "Multiphase Galaxy Halos" Survey. Using a combination of quasar spectra from HST/COS and from Keck/HIRES or VLT/UVES we measure column densities of, or determine limits on, CGM absorption lines. We then use a Monte-Carlo Markov chain approach with Cloudy to estimate the metallicity of cool (T$\sim$$10^4$K) CGM gas. We also use HST images to determine host galaxy inclination and quasar--galaxy azimuthal angles. Our sample spans a HI column density range of $13.8$ cm s$^{-1}<{\log N_{HI}}<19.9$ cm s$^{-1}$. We find (1) while the metallicity distribution appears bimodal, a Hartigan dip test cannot rule out a unimodal distribution ($0.4\sigma$). (2) CGM metallicities are independent of halo mass, spanning three orders of magnitude at fixed halo mass. (3) The CGM metallicity does not depend on the galaxy azimuthal and inclination angles regardless of HI column density, impact parameter and galaxy color. (4) Ionization parameter does not depend on azimuthal angle. We suggest that the partial Lyman limit metallicity bimodality is not driven by a spatial azimuthal bimodality. Our results are consistent with simulations where the CGM is complex and outflowing, accreting, and recycled gas are well-homogenized at $z<0.7$. The presence of low metallicity gas at all orientations suggests that cold streams of accreting filaments are not necessarily aligned with the galaxy plane at low redshifts or intergalactic transfer may dominate. Finally, our results support simulations showing that strong metal absorption can mask the presence of low metallicity gas in integrated line-of-sight CGM metallicities.

## Figures

40 figures with captions in the complete paper: https://tomesphere.com/paper/1907.05557/full.md

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Source: https://tomesphere.com/paper/1907.05557