Where is the Molecular Hydrogen in Damped Lyman-Alpha Absorbers?

We show in this paper why molecular millimeter absorption line searches in DLAs have been unsuccessful. We use CO emission line maps of local galaxies to derive the H2 column density distribution function f(N_H2) at z=0. We show that it forms a natural extension to f(N_HI): the H2 distribution exceeds f(N_HI) at N_H ~ 10^22 cm^-2 and exhibits a power law drop-off with slope ~ -2.5. Approximately 97% of the H2 mass density rho_H2 is in systems above N_H2=10^21 cm^-2. We derive a value rho_H2 = 1.1 x 10^7 h_70 M_sun Mpc^-3, which is ~25% the mass density of atomic hydrogen. Yet, the redshift number density of H2 above this N_H2 limit is only ~3 x 10^-4, a factor 150 lower than that for HI in DLAs at z=0. Furthermore, we show that the median impact parameter between a N_H2>10^21 cm^-2 absorber and the centre of the galaxy hosting the H2 gas is only 2.5 kpc. Based on arguments related to the Schmidt law, we argue that H2 gas above this column density limit is associated with a large fraction of the integral star formation rate density. Even allowing for an increased molecular mass density at higher redshifts, the derived cross-sections indicate that it is very unlikely to identify the bulk of the molecular gas in present quasar absorption lines samples. We discuss the prospects for identifying this molecular mass in future surveys.