Herschel Spectroscopic Observations of LITTLE THINGS Dwarf Galaxies

TL;DR

This study uses Herschel far-infrared spectroscopy to analyze low-metallicity dwarf galaxies, revealing widespread [CII] emission, dominant PDR cooling, and insights into their ISM properties on large star-forming scales.

Contribution

First detailed far-infrared spectral line observations of low surface brightness dwarf galaxies, expanding understanding of their ISM and star formation processes.

Findings

Widespread [CII] emission accounts for ~0.5% of total infrared budget.

[NII] emission is weak, indicating [CII] mainly from PDRs.

Efficient cooling at low dust temperatures observed.

Abstract

We present far-infrared spectral line observations of five galaxies from the LITTLE THINGS sample: DDO 69, DDO 70, DDO 75, DDO 155, and WLM. While most studies of dwarfs focus on bright systems or starbursts due to observational constraints, our data extend the observed parameter space into the regime of low surface brightness dwarf galaxies with low metallicities and moderate star formation rates. Our targets were observed with Herschel at the [CII] 158um, [OI] 63um, [OIII] 88um, and NII 122um emission lines using the PACS Spectrometer. These high-resolution maps allow us for the first time to study the far-infrared properties of these systems on the scales of larger star-forming complexes. The spatial resolution in our maps, in combination with star formation tracers, allows us to identify separate PDRs in some of the regions we observed. Our systems have widespread [CII] emission that is bright relative to continuum, averaging near 0.5% of the total infrared budget - higher than in solar-metallicity galaxies of other types. [NII] is weak, suggesting that the [CII] emission in our galaxies comes mostly from PDRs instead of the diffuse ionized ISM. These systems exhibit efficient cooling at low dust temperatures, as shown by ([OI]+[CII])/TIR in relation to 60um/100um, and low [OI]/[CII] ratios which indicate that [CII] is the dominant coolant of the ISM. We observe [OIII]/[CII] ratios in our galaxies that are lower than those published for other dwarfs, but similar to levels noted in spirals.