Calibrating the HISA temperature: Measuring the temperature of the Riegel-Crutcher cloud

TL;DR

This study measures the temperature of the Riegel-Crutcher HISA cloud using new HI absorption data, revealing a temperature gradient and molecular gas presence, advancing understanding of cold interstellar medium properties.

Contribution

The paper introduces new HI absorption measurements and Gaussian decomposition using machine learning to accurately determine the Riegel-Crutcher cloud's temperature and structure.

Findings

Spin temperature between 20 and 80 K

Temperature gradient across the cloud

Detection of molecular gas via OH absorption lines

Abstract

HI self absorption (HISA) clouds are clumps of cold neutral hydrogen (HI) visible in front of warm background gas, which makes them ideal places to study the properties of the cold atomic component of the interstellar medium (ISM). The Riegel-Crutcher (R-C) cloud is the most striking HISA feature in the Galaxy. It is one of the closest HISA clouds to us and is located in the direction of the Galactic Centre, which provides a bright background. High-resolution interferometric measurements have revealed the filamentary structure of this cloud, however it is difficult to accurately determine the temperature and the density of the gas without optical depth measurements. In this paper we present new HI absorption observations with the Australia Telescope Compact Array (ATCA) against 46 continuum sources behind the Riegel-Crutcher cloud to directly measure the optical depth of the cloud. We decompose the complex HI absorption spectra into Gaussian components using an automated machine learning algorithm. We find 300 Gaussian components, from which 67 are associated with the R-C cloud (0 < v_{LSR} < 10 kms, FWHM < 10 kms). Combining the new HI absorption data with HI emission data from previous surveys we calculate the spin temperature and find it to be between 20 and 80 K. Our measurements uncover a temperature gradient across the cloud with spin temperatures decreasing towards positive Galactic latitudes. We also find three new OH absorption lines associated with the cloud, which support the presence of molecular gas.