Optically Thick H i Does Not Dominate Dark Gas in the Local ISM

The local interstellar medium (ISM) is suffused with "dark" gas, identified by excess infrared and gamma-ray emission, yet undetected by standard ISM tracers such as neutral hydrogen (H i) or carbon monoxide emission. Based on observed dust properties from Planck, recent studies have argue...

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Published inThe Astrophysical journal Vol. 862; no. 2; pp. 131 - 137
Main Authors Murray, Claire E., Peek, J. E. G., Lee, Min-Young, Stanimirovi, Sne ana
Format Journal Article
LanguageEnglish
Published Philadelphia The American Astronomical Society 01.08.2018
IOP Publishing
Subjects
Angular resolution
Astrophysics
Carbon monoxide
Density corrections
Dust
Dust emission
Emission analysis
Emission standards
Gamma emission
Gamma rays
Hydrogen
Hypotheses
Interstellar gas
Interstellar medium
ISM: atoms
ISM: clouds
ISM: molecules
Local interstellar medium
Optical analysis
Optical thickness
Tracers
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Summary:The local interstellar medium (ISM) is suffused with "dark" gas, identified by excess infrared and gamma-ray emission, yet undetected by standard ISM tracers such as neutral hydrogen (H i) or carbon monoxide emission. Based on observed dust properties from Planck, recent studies have argued that H i mixed with dust is strongly saturated and that dark gas is dominated by optically thick H i. We test this hypothesis by reproducing this model using data from Planck and new 21 cm emission maps from GALFA-H i-the first large-area 21 cm emission survey with comparable angular resolution to Planck. We compare the results with those from a large sample of H i column densities based on direct observations of H i optical depth, and find that the inferred column density corrections are significantly lower than those inferred by the Planck-based model. Further, we rule out the hypothesis that the pencil-beam H i absorption sight lines preferentially miss opaque "blobs" with small covering fraction, as these structures require densities and pressures that are incompatible with ISM conditions. Our results support the picture that excess dust emission in the local ISM is not dominated by optically thick H i, but is rather a combination of intrinsic changes in dust grain emissivities and H2 missed by CO observations.
Bibliography:AAS10606
Interstellar Matter and the Local Universe
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/aaccfe