# Synthetic Observations of 21cm HI Line Profiles from Inhomogeneous   Turbulent Interstellar HI Gas with Magnetic Field

**Authors:** Yasuo Fukui, Takahiro Hayakawa, Tsuyoshi Inoue, Kazufumi Torii, Ryuji, Okamoto, Kengo Tachihara, Toshikazu Onishi, Katsuhiro Hayashi

arXiv: 1701.07129 · 2018-06-27

## TL;DR

This study uses magneto-hydrodynamical simulations to generate synthetic 21cm HI line observations, revealing the distinct distributions and observational biases of cold and warm neutral interstellar medium components.

## Contribution

It provides new insights into the spatial distribution and observational signatures of the CNM and WNM in the turbulent interstellar medium using synthetic data.

## Key findings

- CNM is highly filamentary with small filling factor.
- WNM has a smooth, extended distribution with large filling factor.
- Emission-absorption measurements are biased towards WNM, underrepresenting CNM.

## Abstract

We carried out synthetic observations of interstellar atomic hydrogen at 21cm wavelength by utilizing the magneto-hydrodynamical numerical simulations of the inhomogeneous turbulent interstellar medium (ISM) Inoue and Inutsuka (2012). The cold neutral medium (CNM) shows significantly clumpy distribution with a small volume filling factor of 3.5%, whereas the warm neutral medium (WNM) distinctly different smooth distribution with a large filling factor of 96.5%. In projection on the sky, the CNM exhibits highly filamentary distribution with a sub-pc width, whereas the WNM shows smooth extended distribution. In the HI optical depth the CNM is dominant and the contribution of the WNM is negligibly small. The CNM has an area covering factor of 30% in projection, while the WNM has a covering factor of 70%. This causes that the emission-absorption measurements toward radio continuum compact sources tend to sample the WNM with a probability of 70%, yielding smaller HI optical depth and smaller HI column density than those of the bulk HI gas. The emission-absorption measurements, which are significantly affected by the small-scale large fluctuations of the CNM properties, are not suitable to characterize the bulk HI gas. Larger-beam emission measurements which are able to fully sample the HI gas will provide a better tool for that purpose, if a reliable proxy for hydrogen column density, possibly dust optical depth and gamma rays, is available.

## Figures

14 figures with captions in the complete paper: https://tomesphere.com/paper/1701.07129/full.md

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Source: https://tomesphere.com/paper/1701.07129