The HI mass function of star-forming galaxies at z 0.35

Abstract

The neutral atomic hydrogen (HI) mass function (HIMF) describes the distribution of the HI content of galaxies at any epoch; its evolution provides an important probe of models of galaxy formation and evolution. Here, we report Giant Metrewave Radio Telescope HI 21cm spectroscopy of blue star-forming galaxies at z≈0.20-0.42 in the Extended Groth Strip, which has allowed us to determine the scaling relation between the average HI mass (MHI) and the absolute B-band magnitude (MB) of such galaxies at z ≈ 0.35, by stacking the HI 21cm emission signals of galaxy subsamples in different MB ranges. We combine this MHI-MB scaling relation (with a scatter assumed to be equal to that in the local Universe) with the known B-band luminosity function of star-forming galaxies at these redshifts to determine the HIMF at z≈0.35. We show that the use of the correct scatter in the MHI-MB scaling relation is critical for an accurate estimate of the HIMF. We find that the HIMF has evolved significantly from z≈0.35 to z≈0, i.e. over the last four Gyr, especially at the high-mass end. High-mass galaxies, with MHI1010\ M, are a factor of ≈3.4 less prevalent at z≈0.35 than at z ≈ 0. Conversely, there are more low-mass galaxies, with MHI ≈109\ M, at z≈0.35 than in the local Universe. While our results may be affected by cosmic variance, we find that massive star-forming galaxies have acquired a significant amount of HI through merger events or accretion from the circumgalactic medium over the past four Gyr.