# Cosmic-ray induced destruction of CO in star-forming galaxies

**Authors:** Thomas G. Bisbas, Ewine F. van Dishoeck, Padelis P. Papadopoulos,, L\'aszl\'o Sz\"ucs, Shmuel Bialy, Zhi-Yu Zhang

arXiv: 1703.08598 · 2017-04-26

## TL;DR

This study investigates how elevated cosmic ray ionization rates in star-forming galaxies lead to significant CO destruction, affecting molecular cloud observations and the thermal state of the gas, with implications for understanding galaxy evolution.

## Contribution

It expands previous models by incorporating realistic GMC structures, detailed chemical analysis, and thermal effects of cosmic rays on molecular clouds.

## Key findings

- High cosmic ray rates reduce CO abundance, making clouds appear clumpier.
- At very high rates, CO lines become unreliable for galaxy structure analysis.
- OH may help mitigate CO destruction at elevated temperatures.

## Abstract

We explore the effects of the expected higher cosmic ray (CR) ionization rates $\zeta_{\rm CR}$ on the abundances of carbon monoxide (CO), atomic carbon (C), and ionized carbon (C$^+$) in the H$_2$ clouds of star-forming galaxies. The study of Bisbas et al. (2015) is expanded by: a) using realistic inhomogeneous Giant Molecular Cloud (GMC) structures, b) a detailed chemical analysis behind the CR-induced destruction of CO, and c) exploring the thermal state of CR-irradiated molecular gas. CRs permeating the interstellar medium with $\zeta_{\rm CR}$$\gtrsim 10\times$(Galactic) are found to significantly reduce the [CO]/[H$_2$] abundance ratios throughout the mass of a GMC. CO rotational line imaging will then show much clumpier structures than the actual ones. For $\zeta_{\rm CR}$$\gtrsim 100\times$(Galactic) this bias becomes severe, limiting the utility of CO lines for recovering structural and dynamical characteristics of H$_2$-rich galaxies throughout the Universe, including many of the so-called Main Sequence (MS) galaxies where the bulk of cosmic star formation occurs. Both C$^+$ and C abundances increase with rising $\zeta_{\rm CR}$, with C remaining the most abundant of the two throughout H$_2$ clouds, when $\zeta_{\rm CR}\sim (1-100)\times$(Galactic). C$^+$ starts to dominate for $\zeta_{\rm CR}$$\gtrsim 10^3\times$(Galactic). The thermal state of the gas in the inner and denser regions of GMCs is invariant with $T_{\rm gas}\sim 10\,{\rm K}$ for $\zeta_{\rm CR}\sim (1-10)\times$(Galactic). For $\zeta_{\rm CR}$$\sim 10^3\times$(Galactic) this is no longer the case and $T_{\rm gas}\sim 30-50\,{\rm K}$ are reached. Finally we identify OH as the key species whose $T_{\rm gas}-$sensitive abundance could mitigate the destruction of CO at high temperatures.

## Full text

_Full body text omitted from this summary view._ Fetch the complete paper as Markdown: https://tomesphere.com/paper/1703.08598/full.md

## Figures

35 figures with captions in the complete paper: https://tomesphere.com/paper/1703.08598/full.md

## References

128 references — full list in the complete paper: https://tomesphere.com/paper/1703.08598/full.md

---
Source: https://tomesphere.com/paper/1703.08598