# The gas-to-extinction ratio and the gas distribution in the Galaxy

**Authors:** Hui Zhu, Wenwu Tian, Aigen Li, Mengfei Zhang

arXiv: 1706.07109 · 2017-08-30

## TL;DR

This study quantifies the gas-to-extinction ratio across the Galaxy, finds it to be largely invariant, and models the hydrogen distribution vertically and radially, providing key parameters for Galactic gas structure.

## Contribution

It provides a comprehensive measurement of the N_H/A_V ratio across the Galaxy and models the vertical hydrogen distribution with new scale height and density estimates.

## Key findings

- N_H/A_V ratio is approximately 2.08×10^{21} H cm^{-2} mag^{-1} with little variation across the Galaxy.
- Vertical hydrogen distribution follows a Gaussian with a scale height of about 75.5 pc.
- N_H/A_V ratio increases by ~20% when using subsolar abundances instead of solar abundances.

## Abstract

We investigate the relation between the optical extinction ($A_V$) and the hydrogen column density ($N_H$) determined from X-ray observations of a large sample of Galactic sightlines toward 35 supernova remnants, 6 planetary nebulae, and 70 X-ray binaries for which $N_H$ was determined in the literature with solar abundances. We derive an average ratio of ${N_H}/{A_V}=(2.08\pm0.02)\times10^{21}{\rm H\, cm^{-2}\, mag^{-1}}$ for the whole Galaxy. We find no correlation between ${N_H}/{A_V}$ and the number density of hydrogen, the distance away from the Galactic centre, and the distance above or below the Galactic plane. The ${N_H}/{A_V}$ ratio is generally invariant across the Galaxy, with ${N_H}/{A_V}=(2.04\pm0.05)\times10^{21}{\rm H\, cm^{-2}\, mag^{-1}}$ for the 1st and 4th Galactic quadrants and ${N_H}/{A_V}=(2.09\pm0.03)\times10^{21}{\rm H\, cm^{-2}\, mag^{-1}}$ for the 2nd and 3rd Galactic quadrants. We also explore the distribution of hydrogen in the Galaxy by enlarging our sample with additional 74 supernova remnants for which both $N_H$ and distances are known. We find that, between the Galactic radius of 2 kpc to 10 kpc, the vertical distribution of hydrogen can be roughly described by a Gaussian function with a scale height of $h=75.5\pm12.4\,{\rm pc}$ and a mid-plane density of $n_{H}(0)=1.11\pm0.15\,{\rm cm^{-3}}$, corresponding to a total gas surface density of ${\sum}_{gas}{\sim}7.0\,{M_{\bigodot}}\,{\rm pc^{-2}}$. We also compile $N_H$ from 19 supernova remnants and 29 X-ray binaries for which $N_H$ was determined with subsolar abundances. We obtain ${N_H}/{A_V}=(2.47\pm0.04)\times10^{21}{\rm H\, cm^{-2}\, mag^{-1}}$ which exceeds that derived with solar abundances by $\sim$20%. We suggest that in future studies one may simply scale $N_H$ derived from subsolar abundances by a factor of $\sim$1.2 when converting to $N_H$ of solar abundances.

## Full text

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## Figures

29 figures with captions in the complete paper: https://tomesphere.com/paper/1706.07109/full.md

## References

844 references — full list in the complete paper: https://tomesphere.com/paper/1706.07109/full.md

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Source: https://tomesphere.com/paper/1706.07109