A HST/COS survey of molecular hydrogen in DLAs & sub-DLAs at z < 1: Molecular fraction and excitation temperature

Sowgat Muzahid, Raghunathan Srianand, Jane Charlton

Published 2014-10-14Version 1

We present the results of a systematic search for molecular hydrogen (H2) in low redshift (0.05 < z < 0.7) damped and sub-damped Lya absorption systems (DLAs/sub-DLAs) with N(HI) > 10^19.0 cm^{-2}, in the archival Hubble Space Telescope (HST)/Cosmic Origins Spectrograph (COS) spectra. Our core sample is comprised of 27 systems with a median log N(HI) = 19.6. This is a factor of ~ 10 lower than that of the high-z (z > 2) sample of Noterdaeme et al. H2 absorption is detected in 10 cases (3/5 in DLAs and 7/22 in sub-DLAs). On the average, our survey is sensitive down to log N(H2) = 14.4 corresponding to a molecular mass fraction of log f_H2 = -4.9 at the median N(HI). The H2 incidence rate of 50^{+25}_{-12} percent, is a factor of > 2 higher than that of the high-z sample, for systems with N(H2) > 10^14.4 cm^{-2}. The enhanced incidence rate could result from the increase of the cosmic mean metallicities of DLAs and sub-DLAs with cosmic time. In spite of having systematically lower N(HI) values, low-z H2 systems show molecular mass fractions (log f_H2 = -1.93 $\pm$ 0.63) that are comparable to the high-z measurements. The rotational excitation temperatures (T_01 = 133 $\pm$ 55 K), as measured in our low-z sample, are typically consistent with high-z measurements. Simple photoionization models demonstrate that the radiation field prevailing in the low-z H2 systems cannot have an appreciable stellar contribution for densities of 10-100 cm^{-3}. The impact parameters of the nearest possible host-galaxy candidates are typically large (e.g. 10 < $\rho$ (kpc) < 80). We, therefore, conjecture that the low-z H2 bearing gas is not related to star-forming disks but stems from self-shielded, tidally stripped or ejected disk-material in the extended halo.