# Proximate molecular quasar absorbers: Chemical enrichment and kinematics   of the neutral gas

**Authors:** P. Noterdaeme, S. Balashev, R. Cuellar, J.-K. Krogager, F. Combes, A., De Cia, N. Gupta, C. Ledoux, S. L\'opez, R. Srianand

arXiv: 2302.13108 · 2023-05-10

## TL;DR

This study investigates the chemical enrichment and kinematics of proximate molecular quasar absorbers using multi-wavelength spectroscopy, revealing insights into metallicity, dust, and gas dynamics near quasars.

## Contribution

It provides the first detailed analysis of chemical and kinematic properties of proximate molecular absorbers, highlighting differences from intervening systems and the role of the quasar environment.

## Key findings

- Gas-phase metallicities range from 2% to 40% of Solar.
- High-ionisation phase traced by NV is almost ubiquitous.
- No strong deficit of neutral argon despite hard UV fields.

## Abstract

Proximate molecular quasar absorbers (PH2) are an intriguing population of absorption systems recently uncovered through strong H2 absorption at small velocity separation from the background quasars. We performed a multi-wavelength spectroscopic follow-up of thirteen such systems with VLT/X-Shooter. Here, we present the observations and study the overall chemical enrichment measured from the HI, H2 and metal lines. We combine this with an investigation of the neutral gas kinematics with respect to the quasar host. We find gas-phase metallicities in the range 2% to 40% of the Solar value, i.e. in the upper-half range of HI-selected proximate damped Lyman-alpha systems, but similar to what is seen in intervening H2-bearing systems. This is likely driven by similar selection effects that play against the detection of most metal and molecular rich systems in absorption. Differences are however seen in the abundance of dust (from [Zn/Fe]) and its depletion pattern, when compared to intervening systems, possibly indicating different dust production or destruction close to the AGN. We also note the almost-ubiquitous presence of a high-ionisation phase traced by NV in proximate systems. In spite of the hard UV field from the quasars, we found no strong overall deficit of neutral argon, at least when compared to intervening DLAs. This likely results from argon being mostly neutral in the H2 phase, which actually accounts for a large fraction of the total amount of metals. We measure the quasar systemic redshifts through emission lines from both ionised gas and CO(3-2) emission, the latter being detected in all 6 cases for which we obtained 3-mm data from complementary NOEMA observations. For the first time, we observe a trend between line-of-sight velocity with respect to systemic redshift and metallicity of the absorbing gas. [truncated]

## Full text

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## Figures

63 figures with captions in the complete paper: https://tomesphere.com/paper/2302.13108/full.md

## References

97 references — full list in the complete paper: https://tomesphere.com/paper/2302.13108/full.md

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Source: https://tomesphere.com/paper/2302.13108