Molecular gas and star formation in an absorption-selected galaxy: Hitting the bull's eye at z = 2.46

TL;DR

This study analyzes a high-column-density molecular cloud at z=2.46, revealing its physical and chemical properties, and its likely location within a galaxy's ISM, providing insights into early universe star formation.

Contribution

It presents the highest H$_2$ column density measured in an intervening system and combines observational data with theoretical modeling to study atomic-to-molecular hydrogen transition at high redshift.

Findings

Highest H$_2$ column density in an intervening damped Lyman-alpha system

Detection of Ly-$$ emission close to the absorber

Constraints on UV flux consistent with star formation rate estimates

Abstract

We present the detection analysis of a diffuse molecular cloud at z$_{abs}$=2.4636 towards the quasar SDSS J1513+0352(z$_{em}\,\simeq$ 2.68) observed with the X-shooter spectrograph(VLT). We measure very high column densities of atomic and molecular hydrogen, with log N(HI,H$_2$)$\simeq$21.8,21.3. This is the highest H$_2$ column density ever measured in an intervening damped Lyman-alpha system but we do not detect CO, implying log N(CO)/N(H$_2$) < -7.8, which could be due to a low metallicity of the cloud. From the metal absorption lines, we derive the metallicity to be Z $\simeq$ 0.15 Z$_{\odot}$ and determine the amount of dust by measuring the induced extinction of the background quasar light, A$_V$ $\simeq$ 0.4. We also detect Ly-$\alpha$ emission at the same redshift, with a centroid located at a most probable impact parameter of only $\rho\,\simeq$ 1.4 kpc. We argue that the line of sight is therefore likely passing through the ISM of a galaxy as opposed to the CGM. The relation between the surface density of gas and that of star formation seems to follow the global empirical relation derived in the nearby Universe although our constraints on the star formation rate and on the galaxy extent remain too loose to be conclusive. We study the transition from atomic to molecular hydrogen using a theoretical description based on the microphysics of molecular hydrogen. We use the derived chemical properties of the cloud and physical conditions (T$_k\,\simeq$90 K and n$\simeq$250 cm$^{-3}$ derived through the excitation of H$_2$ rotational levels and neutral carbon fine structure transitions to constrain the fundamental parameters that govern this transition. By comparing the theoretical and observed HI column densities, we are able to bring an independent constraint on the incident UV flux, which we find to be in agreement with that estimated from the observed star formation rate.