Abstract
While molecular quasar absorption systems provide unique probes of the physical and chemical properties of the gas as well as original constraints on fundamental physics and cosmology, their detection remains challenging. Here we present the results from a complete survey for molecular gas in thirty-nine absorption systems selected solely upon the detection of neutral carbon lines in Sloan Digital Sky Survey (SDSS) spectra, without any prior knowledge of the atomic or molecular gas content. H2 is found in all twelve systems (including seven new detections) where the corresponding lines are covered by the instrument setups and measured to have logN(H2) ≳ 18, indicating a self-shielded regime. We also report seven CO detections (7/39) down to logN(CO) ~ 13.5, including a new one, and put stringent constraints on N(CO) for the remaining 32 systems. N(CO) and N(C I) are found to be strongly correlated with N(CO)/N(C I) ~ 1/10. This suggests that the C I-selected absorber population is probing gas deeper than the H I–H2 transition in which a substantial fraction of the total hydrogen in the cloud is in the form of H2. We conclude that targeting C I-bearing absorbers is a very efficient way to find high-metallicity molecular absorbers. However, probing the molecular content in lower-metallicity regimes as well as high-column-density neutral gas remains to be undertaken to unravel the processes of gas conversion in normal high-z galaxies.
Highlights
The detection and analysis of molecular absorption lines along the lines of sight to background light sources has proven to be an extremely useful tool to investigate the physical and chemical state of the interstellar medium (ISM) thanks to the sensitive formation, destruction, and excitation processes of molecules
We present the results from a complete survey for molecular gas in thirty-nine absorption systems selected solely upon the detection of neutral carbon lines in Sloan Digital Sky Survey (SDSS) spectra, without any prior knowledge of the atomic or molecular gas content
Such a technique applies from the solar neighbourhood towards nearby stars (e.g. Savage et al 1977; Boissé et al 2013) to the gas in and around high-redshift galaxies revealed by damped Lyman-α systems (DLAs; e.g. Levshakov et al 1989; Ge et al 1997; Petitjean et al 2000; Cui et al 2005; Srianand et al 2005; Noterdaeme et al 2008; Jorgenson et al 2010; Carswell et al 2011; Balashev et al 2017)
Summary
The detection and analysis of molecular absorption lines along the lines of sight to background light sources has proven to be an extremely useful tool to investigate the physical and chemical state of the interstellar medium (ISM) thanks to the sensitive formation, destruction, and excitation processes of molecules. Such a technique applies from the solar neighbourhood towards nearby stars With the Ultraviolet and Visual Echelle Spectrograph (UVES) at a resolving power R ∼ 50 000 and the X-shooter spectrograph (R ∼ 5000) at the Very Large Telescope (VLT)
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