A New Constraint on the Physical Nature of Damped Lyman Alpha Systems

TL;DR

This paper introduces a novel method to measure the size of Damped Lyman Alpha systems (DLAs) using extended background sources, revealing that high-column-density neutral gas can span much larger areas than previously observed in quasar sightlines.

Contribution

The study presents the first direct measurement of DLA extent using extended background galaxies, demonstrating that DLAs can cover vast areas and contain enough gas to fuel galaxy formation.

Findings

A high-column-density DLA covers 90-100% of a background galaxy's luminous extent.

DLAs can span areas 10^8 to 10^10 times larger than in prior quasar sightline studies.

DLAs contain sufficient gas mass to serve as fuel for galaxy formation.

Abstract

The formation and evolution of galaxies require large reservoirs of cold, neutral gas. The damped Lya systems (DLAs), seen in absorption towards distant quasars and gamma-ray bursts, are predicted to be the dominant reservoirs for this gas. Detailed properties of DLAs have been studied extensively for decades with great success. However, their size, fundamental in understanding their nature, has remained elusive, as quasar and gamma-ray-burst sightlines only probe comparatively tiny areas of the foreground DLAs. Here, we introduce a new approach to measure the full extent of DLAs in the sightlines toward extended background sources. We present the discovery of a high-column-density (log N(HI) = 21.1 +/-0.4 cm^-2) DLA at z ~ 2.4 covering 90-100% of the luminous extent of a line-of-sight background galaxy. Estimates of the size of the background galaxy range from a minimum of a few kpc^2, to ~100 kpc^2, and demonstrate that high-column density neutral gas can span continuous areas 10^8 - 10^10 times larger than previously explored in quasar or gamma-ray burst sightlines. The DLA presented here is the first from a sample of DLAs in our pilot survey that searches Lyman break and Lyman continuum galaxies at high redshift. The low luminosities, large sizes, and mass contents (>~10^6 - 10^9 M_solar) implied by this DLA and the early data suggest that DLAs contain the necessary fuel for galaxies, with many systems consistent with relatively massive, low-luminosity primeval galaxies.