We report statistically significant detection of H I 21-cm emission from intermediate-redshift (z0. 2-0. 6) galaxies. By leveraging multi-sightline galaxy survey data from the Cosmic Ultraviolet Baryon Survey (CUBS) and deep radio observations from the MeerKAT Absorption Line Survey (MALS), we have established a sample of 6000 spectroscopically identified galaxies in 11 distinct fields to constrain the neutral gas content at intermediate redshifts. The galaxies sample a broad range in stellar mass -- 8ₒₓ₀ₑ/₌_11 with a median of ₒₓ₀ₑ/₌_ₘed10 -- and a wide range in redshift -- 0. 24 z0. 63 with a median of zₘed=0. 44. Our detected emission-line signal exceeds 4\, σ significance in the stacked spectra of all subsamples, and the observed total H I 21-cm line flux translates to a H I mass MH\;I10^10M_. We find a high H I-to-stellar mass ratio of MH\;I/Mₛtar6 for low-mass galaxies with ₒₓ₀ₑ/₌_ 9. 3 (>3. 7\, σ). For galaxies with ₒₓ₀ₑ/₌_10. 6, we find MH\;I/Mₛtar0. 3 (>4. 7\, σ). Additionally, the redshift evolution of H I mass in both low- and high-mass field galaxies, inferred from the stacked emission-line signal, aligns well with the expectation from the cosmic star formation history. This suggests that the overall decline in the cosmic star formation activity across the general galaxy population may be connected to a decreasing supply of neutral hydrogen. Finally, our analysis has revealed significant 21-cm signals at distances greater than 75 kpc from these intermediate-redshift galaxies, indicating a substantial reservoir of H I gas in their extended surroundings.
DePalma et al. (Fri,) studied this question.