Photodissociation Region Diagnostics Across Galactic Environments

TL;DR

This paper uses advanced simulations to analyze how various interstellar medium conditions affect molecular cloud chemistry and emissions, providing new insights into gas tracers and diagnostics across different galactic environments.

Contribution

It offers novel three-dimensional astrochemical simulations that explore a wide parameter space, including cosmic rays, metallicity, and turbulence, to improve understanding of molecular cloud diagnostics.

Findings

Enhanced cosmic-ray densities increase line intensities.

[CII] emission correlates with H2 at low metallicity.

Conversion factors depend on metallicity and cosmic rays, not FUV.

Abstract

We present three-dimensional astrochemical simulations and synthetic observations of magnetised, turbulent, self-gravitating molecular clouds. We explore various galactic interstellar medium environments, including cosmic-ray ionization rates in the range of $\zeta_{\rm CR}=10^{-17}$-$10^{-14}\,{\rm s}^{-1}$, far-UV intensities in the range of $G_0=1$-$10^3$ and metallicities in the range of $Z=0.1$-$2\,{\rm Z}_{\odot}$. The simulations also probe a range of densities and levels of turbulence, including cases where the gas has undergone recent compression due to cloud-cloud collisions. We examine: i) the column densities of carbon species across the cycle of CII, CI and CO, along with OI, in relation to the HI-to-H$_2$ transition; ii) the velocity-integrated emission of [CII]~$158\mu$m, [$^{13}$CII]~$158\mu$m, [CI]~$609\mu$m and $370\mu$m, [OI]~$63\mu$m and $146\mu$m, and of the first ten $^{12}$CO rotational transitions; iii) the corresponding Spectral Line Energy Distributions; iv) the usage of [CII] and [OI]~$63\mu$m to describe the dynamical state of the clouds; v) the behavior of the most commonly used ratios between transitions of CO and [CI]; and vi) the conversion factors for using CO and CI as H$_2$-gas tracers. We find that enhanced cosmic-ray energy densities enhance all aforementioned line intensities. At low metallicities, the emission of [CII] is well connected with the H$_2$ column, making it a promising new H$_2$ tracer in metal-poor environments. The conversion factors of $X_{\rm CO}$ and $X_{\rm CI}$ depend on metallicity and the cosmic-ray ionization rate, but not on FUV intensity. In the era of ALMA, SOFIA and the forthcoming CCAT-prime telescope, our results can be used to understand better the behaviour of systems in a wide range of galactic and extragalactic environments.