The JHU-SDSS metal absorption line catalog: redshift evolution and properties of Mg II absorbers

TL;DR

This paper introduces an automatic method for detecting metal absorption lines in quasar spectra, compiles a large catalog of Mg II absorbers, and finds their evolution closely mirrors cosmic star formation history.

Contribution

A novel automated algorithm using nonnegative matrix factorization for detecting absorption lines and a comprehensive Mg II absorber catalog covering 0.4<z<2.3.

Findings

Rest equivalent width distribution of Mg II absorbers follows an exponential pattern.

Incidence rate of Mg II absorbers up to z~5 can be parametrized with a new model.

Redshift evolution of Mg II absorbers parallels cosmic star formation history.

Abstract

We present a generic and fully-automatic method aimed at detecting absorption lines in the spectra of astronomical objects. The algorithm estimates the source continuum flux using a dimensionality reduction technique, nonnegative matrix factorization, and then detects and identifies metal absorption lines. We apply it to a sample of ~100,000 quasar spectra from the Sloan Digital Sky Survey and compile a sample of ~40,000 Mg II & Fe II absorber systems, spanning the redshift range 0.4< z < 2.3. The corresponding catalog is publicly available. We study the statistical properties of these absorber systems and find that the rest equivalent width distribution of strong Mg II absorbers follows an exponential distribution at all redshifts, confirming previous studies. Combining our results with recent near-infrared observations of Mg II absorbers we introduce a new parametrization that fully describes the incidence rate of these systems up to z~5. We find the redshift evolution of strong Mg II absorbers to be remarkably similar to the cosmic star formation history over 0.4<z<5.5 (the entire redshift range covered by observations), suggesting a physical link between these two quantities.