The Herschel M33 extended survey (HerM33es): PACS spectroscopy of the star forming region BCLMP 302

TL;DR

This study uses Herschel PACS and HIFI spectroscopy to analyze the [CII] emission in a star-forming region of galaxy M33, revealing the contributions of different ISM phases and the properties of gas heating.

Contribution

It provides the first detailed spatial and spectral analysis of [CII], [OI], and other FIR lines in M33's star-forming region, quantifying the ionized gas contribution and gas heating efficiency.

Findings

20-30% of [CII] emission originates from ionized gas.

[CII] line is broader and slightly blue-shifted compared to CO.

Gas heating efficiency varies from 0.07% to 1.5%.

Abstract

Context: The emission line of [CII] at 158 micron is one of the strongest cooling lines of the interstellar medium (ISM) in galaxies. Aims: Disentangling the relative contributions of the different ISM phases to [CII] emission, is a major topic of the HerM33es program, a Herschel key project to study the ISM in the nearby spiral galaxy M33. Methods: Using PACS, we have mapped the emission of [CII] 158 micron, [OI] 63 micron, and other FIR lines in a 2'x2' region of the northern spiral arm of M33, centered on the HII region BCLMP302. At the peak of H-alpha emission, we have observed in addition a velocity resolved [CII] spectrum using HIFI. We use scatterplots to compare these data with PACS 160 micron continuum maps, and with maps of CO and HI data, at a common resolution of 12 arcsec or 50 pc. Maps of H-alpha and 24 micron emission observed with Spitzer are used to estimate the SFR. We have created maps of the [CII] and [OI] 63 micron emission and detected [NII] 122 micron and NIII 57 micron at individual positions. Results: The [CII] line observed with HIFI is significantly broader than that of CO, and slightly blue-shifted. In addition, there is little spatial correlation between [CII] observed with PACS and CO over the mapped region. There is even less spatial correlation between [CII] and the atomic gas traced by HI. Detailed comparison of the observed intensities towards the HII region with models of photo ionization and photon dominated regions, confirms that a significant fraction, 20--30%, of the observed [CII] emission stems from the ionized gas and not from the molecular cloud. The gas heating efficiency, using the ratio between [CII] and the TIR as a proxy, varies between 0.07 and 1.5%, with the largest variations found outside the HII region.