Dissecting the Mid-Infrared Heart of M83 with JWST

Svea Hernandez, Logan Jones, Linda J. Smith, Aditya Togi, Alessandra Aloisi, William P. Blair, Alec S. Hirschauer, Leslie K. Hunt, Bethan L. James, Nimisha Kumari, Matilde Mingozzi, Lise Ramambason

Published 2023-01-23Version 1

We present a first look at the MRS observations of the nucleus of the spiral galaxy M83, taken with MIRI onboard JWST. The observations show a rich set of emission features from the ionized and warm molecular gas, as well as traces of the dust properties in this highly star forming environment. To begin dissecting the complex processes taking place in this part of the galaxy, we divide the nucleus observations into four different regions. We find that the strength of the emission features appears to strongly vary in all four regions, with the south-east region displaying the weakest features tracing both the dust continuum and ISM properties. Comparison between the cold molecular gas traced by the $^{12}$CO (1-0) transition with ALMA and the H$_2$ 0-0 S(1) transition showed a similar spatial distribution throughout the nucleus. This is in contrast to the distribution of the much warmer H$_2$ emission from the S(7) transition found to be concentrated mainly around the optical nucleus. We modeled the H$_2$ excitation using the rotational emission lines and estimate a total molecular gas mass accounting for the warm H$_2$ component of M($>$50 K)$_{\rm H_{2}}$ = 59.33 ($\pm 4.75$) $\times$ 10$^{6}$ M$_{\odot}$. We compared this value to the total molecular gas mass inferred by probing the cold H$_2$ gas through the $^{12}$CO (1-0) emission, M(CO)$_{\rm H_{2}}$ = 14.99 $\times$ 10$^{6}$ M$_{\odot}$. Our findings indicate that $\sim$75\% of the total molecular gas mass in the core of M83 is contained in the warm H$_2$ component. We also identify [OIV]25.89 $\mu$m and [FeII]25.99 $\mu$m emission (indicative of shocks) in all four nuclear regions with the strongest emission originating from the north-west section. We propose that the diffuse [FeII]25.99 $\mu$m emission is an indication of the combined effects of both the collective supernova explosions and the starbursts themselves.