# Observational study of hydrocarbons in the bright photodissociation   region of Messier 8

**Authors:** M. Tiwari, K. M. Menten, F. Wyrowski, J. P. P\'erez-Beaupuits, M.-Y., Lee, W.-J. Kim

arXiv: 1903.10444 · 2019-06-12

## TL;DR

This study investigates hydrocarbons in the bright PDR of M8, combining observations and models to understand their formation, physical conditions, and relation to PAHs, revealing gas-phase chemistry's role in high-UV environments.

## Contribution

It provides new observational data and modeling insights into hydrocarbon formation and distribution in M8's PDR, highlighting the limited role of PAHs in small hydrocarbon production.

## Key findings

- Hydrocarbon abundances are around 10^{-8} for C2H and 10^{-9} for c-C3H2.
- Volume densities of hydrocarbon-emitting gas range from 5×10^4 to 5×10^6 cm^{-3}.
- Gas-phase chemistry explains hydrocarbon abundances in high-UV flux PDRs.

## Abstract

Hydrocarbons are ubiquitous in the interstellar medium, but their formation is still not well understood, depending on the physical environment they are found in. M8 is host to one of the brightest HII regions and PDRs in our galaxy. Using the APEX, and the IRAM 30 m telescopes, we performed a line survey toward Herschel 36 (Her 36), which is the main ionizing stellar system in M8, and an imaging survey within 1.3 $\times$ 1.3 pc around Her 36 of various transitions of C$_{2}$H and c-C$_{3}$H$_{2}$. We used both LTE and non-LTE methods to determine the physical conditions of the emitting gas along with the column densities and abundances of the observed species, which we compared with (updated) gas phase photochemical PDR models. In order to examine the role of PAHs in the formation of small hydrocarbons and to investigate their association with M8, we compared archival GLIMPSE 8 $\mu$m and the SPIRE 250 $\mu$m continuum images with the C$_{2}$H emission maps. We observed a total of three rotational transitions of C$_{2}$H with their hyperfine structure components and four rotational transitions of c-C$_{3}$H$_{2}$ with ortho and para symmetries toward M8. Fragmentation of PAHs seems less likely to contribute to the formation of small hydrocarbons as the 8 $\mu$m emission does not follow the distribution of C$_{2}$H emission, which is more associated with the molecular cloud. From the quantitative analysis, we obtained abundances of $\sim$ 10$^{-8}$ and 10$^{-9}$ for C$_{2}$H and c-C$_{3}$H$_{2}$ respectively, and volume densities of the hydrocarbon emitting gas in the range $n(\rm H_2)$ $\sim$ 5 $\times$ 10$^{4}$--5 $\times$ 10$^{6}$ cm$^{-3}$. The observed column densities of C$_{2}$H and c-C$_3$H$_{2}$ are reproduced reasonably well by our PDR models. This supports the idea that in high-UV flux PDRs, gas phase chemistry is sufficient to explain hydrocarbon abundances.

## Full text

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## Figures

47 figures with captions in the complete paper: https://tomesphere.com/paper/1903.10444/full.md

## References

55 references — full list in the complete paper: https://tomesphere.com/paper/1903.10444/full.md

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Source: https://tomesphere.com/paper/1903.10444