A Photodissociation Region study of NGC 4038

TL;DR

This study models the photodissociation regions in NGC 4038, analyzing multiple emission lines to understand the physical conditions of different gas components and estimating the CO-to-H2 conversion factor.

Contribution

It provides a comprehensive grid of simulations of PDRs in NGC 4038, comparing results with observations to distinguish gas components and refine the CO conversion factor.

Findings

Different gas components traced by molecular and atomic lines.

High-J CO lines indicate dense gas with specific UV interactions.

The CO-to-H2 conversion factor is lower than the Milky Way standard.

Abstract

We present a model of the photodissociation regions of NGC 4038, which is part of the Antennae galaxies. We have considered one-dimensional slabs of uniform density all having a maximum $A_V=10\,{\rm mag}$, interacting with plane-parallel radiation. The density range in our simulations spans four orders of magnitude ($100\le n\le 10^6\,{\rm cm}^{-3}$) and the UV field strength spans more than three orders of magnitude ($10\le\chi\le10^{4.5}$ multiples of the ${\rm Draine}$ field), from which we generated a grid of about 1400 simulations. We compare our results with Herschel SPIRE-FTS, CSO and ISO-LWS observations of eight CO transition lines ($J=1-0$ to $8-7$) and the [CI] 609\mu m and [OI] 146\mu m fine structure lines. We find that the molecular and atomic emission lines trace different gas components of NGC 4038, thus single emission models are insufficient to reproduce the observed values. In general, low-$J$ CO transition lines correspond to either low density regions interacting with low UV field strengths, or high density regions interacting with high UV field strengths. Higher $J$ CO transition lines are less dependent on the UV field strength and are fitted by gas with density $n\sim10^{4.5}-10^{5.2}\,{\rm cm}^{-3}$. We find that the observed fine structure line ratio of [CI] 609\mu m/[OI] 146\mu m is reproduced by clouds subject to weaker UV fields compared to the CO lines. We make estimates of the $X_{\rm CO}$ factor which relates the CO emission with the column density of molecular hydrogen, and find that it is less than the canonical Milky Way value.