Radio Recombination Line Observations at $1.0-1.5$ GHz with FAST

TL;DR

This study demonstrates FAST's capability to detect radio recombination lines in HII regions at 1.0-1.5 GHz, enabling detailed physical parameter measurements and advancing understanding of Galactic structure.

Contribution

First pilot survey using FAST to detect multiple RRLs in HII regions, showcasing its sensitivity and potential for large-scale Galactic studies.

Findings

Detected 21 RRLs simultaneously in nine HII regions

Achieved 100% detection rate for H167α and C167α lines

Measured electron density, temperature, and pressure in three regions

Abstract

HII regions made of gas ionized by radiations from young massive stars, are widely distributed in the Milky Way. They are tracers for star formation, and their distributions are correlated with the Galactic spiral structure. Radio recombination lines (RRLs) of hydrogen and other atoms allows for the precisest determination of physical parameters such as temperature and density. However, RRLs at around 1.4 GHz from HII regions are weak and their detections are difficult. As a result, only a limited number of detections have been obtained yet. The 19-beam receiver on board of the Five-hundred-meter Aperture Spherical radio Telescope (FAST) can simultaneously cover 23 RRLs for H$n{\alpha}$, He$n{\alpha}$, and C$n{\alpha}$ ($n = 164 - 186$), respectively. This, combined with its unparalleled collecting area, makes FAST the most powerful telescope to detect weak RRLs. In this pilot survey, we use FAST to observe nine HII regions at L band. We allocate 20 minutes pointing time for each source to achieve a sensitivity of around 9 mK in a velocity resolution of 2.0 km/s. In total, 21 RRLs for H$n{\alpha}$ and C$n{\alpha}$ at $1.0 - 1.5$ GHz have been simultaneously detected with strong emission signals. Overall, the detection rates for the H167${\alpha}$ and C167${\alpha}$ RRLs are 100%, while that for the He167${\alpha}$ RRL is 33.3%. Using hydrogen and helium RRLs, we measure the electron density, electron temperature, and pressure for three HII regions. This pilot survey demonstrates the capability of FAST in RRL measurements, and a statistically meaningful sample with RRL detection, through which knowledges about Galactic spiral structure and evolution can be obtained, is expected in the future.