Deep extragalactic HI survey of the COSMOS field with FAST

TL;DR

This paper reports a deep HI survey of the COSMOS field using FAST, detecting 80 sources, and reveals that interacting galaxy systems have higher HI content in their surrounding medium compared to isolated galaxies.

Contribution

It introduces a deep, high-sensitivity HI survey with FAST in the COSMOS field, demonstrating the synergy with MeerKAT and providing new insights into HI distribution around different galaxy environments.

Findings

Detected 80 HI sources, 56 cross-matched with MIGHTEE.

Found higher HI mass fraction in CGM and IGM of interacting systems.

Showcased potential for combined FAST and MeerKAT studies.

Abstract

We present a deep HI survey at L-band conducted with the Five-hundred-meter Aperture Spherical radio Telescope (FAST) over the COSMOS field. This survey is strategically designed to overlap with the MIGHTEE COSMOS field, aiming to combine the sensitivity of the FAST and high-resolution of the MeerKAT. We observed the field with FAST for approximately 11 hours covering $\sim$2 square degrees, and reduced the raw data to HI spectral cubes over the frequency range 1310-1420 MHz. The FAST-HI data reach a median 3$\sigma$ column density of $N_{\rm HI}\sim2\times10^{17}$ cm$^{-2}$ over a 5 km s$^{-1}$ channel width, allowing for studies of the distribution of HI gas in various environments, such as in galaxies, the Circum-Galactic Medium (CGM) and Intergalactic Medium (IGM). We visually searched the spectral cubes for HI sources, and found a total of 80 HI detections, of which 56 have been cross-matched with the MIGHTEE-HI catalogue. With the cross-matched sources, we compare their HI masses and find that the total HI mass fraction in the IGM and CGM surrounding the galaxy pairs is statistically higher than the HI fraction surrounding the isolated galaxies by a difference of 13$\pm$4%, indicating that the CGM and IGM associated with interacting systems are richer in neutral hydrogen compared to those around isolated galaxies in the local Universe. We also describe several FAST-MeerKAT synergy projects, highlighting the full potential of exploiting both single-dish and interferometric observations to study the distribution and evolution of the diffuse HI gas.