Physical conditions and redshift evolution of optically thin C III absorbers: Low-z sample

Abstract

We present a detailed analysis of 99 optically thin C III absorption systems at redshift, 0.2 z 0.9 associated with neutral hydrogen column densities in the range, 15 log N H\,I (cm-2) 16.2. Using photoionization models, we infer the number density (n H), C-abundance ([C/H]) and line-of-sight thickness (L) of these systems in the ranges, -3.4 log n H (in cm-3) -1.6, -1.6 [C/H] 0.4, and 1.3 pc L 10 kpc, respectively with most of the systems having sub-kpc scale thickness. We combine the low-z and previously reported high-z (2.1 z 3.3) optically thin C III systems to study the redshift evolution and various correlation between the derived physical parameters. We see a significant redshift evolution in n H, [C/H] and L. We compare the redshift evolution of metallicity in C III systems with those of various types of absorption systems. We find that the slope of [C/H] vs. z for C III absorbers is stepper compared to the redshift evolution of cosmic metallicity of the damped \ sample (DLAs) but consistent with that of sub-DLAs. We find the existence of strong anti-correlation between L vs. [C/H] for the combined sample with a significance level of 8.39σ. We see evidence of two distinct [C/H] branch C III populations (low-[C/H] branch, [C/H] -1.2 and high-[C/H] branch, [C/H] > -1.2) in the combined C III sample when divided appropriately in the L vs. N C\,III plane. Further studies of C III absorbers in the redshift range, 1.0 z 2.0 is important to map the redshift evolution of these absorbers and gain insights into the time evolution physical conditions of the circumgalactic medium.