Exploring quasar evolution with proximate molecular absorbers: Insights from the kinematics of highly ionized nitrogen

TL;DR

This study examines the kinematics and ionization of proximate NV absorption in high-redshift quasars, revealing insights into quasar evolution, outflows, and the molecular environment through spectroscopic analysis.

Contribution

It provides the first detailed kinematic and ionization analysis of NV absorbers near quasars, linking absorption features to evolutionary stages and gas dynamics.

Findings

High NV detection rate (~70%) near quasars compared to intervening systems.

Decoupled kinematics of high-ionization NV from low-ionization species.

Velocity-dependent ionization conditions, with blueshifted NV showing higher ionization.

Abstract

We investigate the presence and kinematics of NV absorption proximate to high redshift quasars selected upon the presence of strong $H_{2}$ and HI absorption at the quasar redshift. Our spectroscopic observations with X-shooter at the VLT reveal a 70% detection rate of NV (9 of 13 quasars with 2.5 < z < 3.3), remarkably higher than the 10% detection rate in intervening DLA systems and the 30% rate observed within a few thousand km/s of the source in the general quasar population. While many NV components lie within the velocity range of the neutral gas, the kinematic profiles of high-ionization species appear decoupled from those of low-ionization species, with the former extending over much larger velocity ranges, particularly towards bluer velocities. We also observe significant variations in the NV/SiIV, which we attribute to varying ionization conditions, with a velocity-dependent trend: blueshifted NV components systematically exhibit higher ionization parameters compared to those near the quasar's systemic redshift. Furthermore, the most redshifted systems relative to the quasar show no evidence of NV absorption. The results suggest that proximate $H_{2}$ absorption systems select critical stages of quasar evolution, during which the quasar remains embedded in a rich molecular environment. Redshifted systems trace infalling gas, potentially associated with mergers, preceding the onset of outflows. Such outflows may reach or even carry out neutral and molecular gas.This latter stage would correspond to proximate $H_{2}$ systems located around or blueshifted relative to the quasar's systemic z. Finally, the only case in our sample featuring highly blueshifted neutral gas shows no evidence of an association with the quasar.Our findings highlight the need to account for the ionization state when defining a velocity threshold to distinguish quasar-associated systems from intervening.