Adaptive Optics Imaging of a Massive Galaxy Associated with a Metal-rich Absorber

TL;DR

This study uses adaptive optics imaging to identify and analyze a massive, metal-rich galaxy responsible for a high-metallicity sub-DLA absorber at z=0.72, revealing its structure, luminosity, and stellar mass.

Contribution

First application of LGSAO imaging to study the galaxy producing a distant quasar absorber, demonstrating the connection between a massive bulge-dominated galaxy and a metal-rich sub-DLA.

Findings

Identified a massive galaxy with a bulge-to-total ratio of 0.4-1.0.

Galaxy has a stellar mass > 10^{11} M_sun.

The galaxy is responsible for the metal-rich sub-DLA at z=0.72.

Abstract

The damped and sub-damped Lyman-alpha absorption line systems in quasar spectra are believed to be produced by intervening galaxies. However, the connection of quasar absorbers to galaxies is not well-understood, since attempts to image the absorbing galaxies have often failed. While most DLAs appear to be metal-poor, a population of metal-rich absorbers, mostly sub-DLAs, has been discovered in recent studies. Here we report high-resolution K-band imaging with the Keck Laser Guide Star Adaptive Optics (LGSAO) system of the field of quasar SDSSJ1323-0021 in search of the galaxy producing the z = 0.72 sub-DLA absorber. With a metallicity of 2-4 times the solar level, this absorber is of the most metal-rich systems found to date. Our data show a large bright galaxy with an angular separation of only 1.25" from the quasar, well-resolved from the quasar at the high resolution of our data. The galaxy has a magnitude of K = 17.6-17.9, which corresponds to a luminosity of ~ 3-6 L*. Morphologically, the galaxy is fit with a model with an effective radius, enclosing half the total light, of R_e = 4 kpc and a bulge-to-total ratio of 0.4-1.0, indicating a substantial bulge stellar population. Based on the mass-metallicity relation of nearby galaxies, the absorber galaxy appears to have a stellar mass > 10^{11} M_sun. Given the small impact parameter, this massive galaxy appears to be responsible for the metal-rich sub-DLA. The absorber galaxy is consistent with the metallicity-luminosity relation observed for nearby galaxies, but is near the upper end of metallicity. Our study marks the first application of LGSAO for study of structure of galaxies producing distant quasar absorbers. Finally, this study offers the first example of a massive galaxy with a substantial bulge producing a metal-rich absorber.