Quasar 2175 {\AA} dust absorbers I: metallicity, depletion pattern, and kinematics

TL;DR

This study identifies and analyzes 13 new 2175 Å dust absorbers at redshifts 1.0-2.2, revealing their metallicity, depletion patterns, and kinematic properties, which suggest they are more massive than typical DLA hosts.

Contribution

First detailed analysis of 2175 Å dust absorbers at these redshifts, showing their depletion patterns and kinematics, and comparing them to Milky Way clouds and DLA systems.

Findings

Depletion patterns resemble Milky Way clouds.

Higher depletion levels than DLA/subDLA systems.

Velocity widths suggest more massive host galaxies.

Abstract

We present 13 new 2175 {\AA} dust absorbers at z_abs = 1.0 - 2.2 towards background quasars from the Sloan Digital Sky Survey. These absorbers are examined in detail using data from the Echelle Spectrograph and Imager (ESI) on the Keck II telescope. Many low-ionization lines including Fe II, Zn II, Mg II, Si II, Al II, Ni II, Mn II, Cr II, Ti II, and Ca II are present in the same absorber which gives rise to the 2175 {\AA} bump. The relative metal abundances (with respect to Zn) demonstrate that the depletion patterns of our 2175 {\AA} dust absorbers resemble that of the Milky Way clouds although some are disk-like and some are halo-like. The 2175 {\AA} dust absorbers have significantly higher depletion levels compared to literature Damped Lyman-{\alpha} absorbers (DLAs) and subDLAs. The dust depletion level indicator [Fe/Zn] tends to anti-correlate with bump strengths. The velocity profiles from the Keck/ESI spectra also provide kinematical information on the dust absorbers. The dust absorbers are found to have multiple velocity components with velocity widths extending from ~100 to ~ 600 km/s, which are larger than those of most DLAs and subDLAs. Assuming the velocity width is a reliable tracer of stellar mass, the host galaxies of 2175 {\AA} dust absorbers are expected to be more massive than DLA/subDLA hosts. Not all of the 2175 {\AA} dust absorbers are intervening systems towards background quasars. The absorbers towards quasars J1006+1538 and J1047+3423 are proximate systems that could be associated with the quasar itself or the host galaxy.