The Structure of Dark Molecular Gas in the Galaxy. II. Physical State of "CO-dark" Gas in the Perseus Arm

The Structure of Dark Molecular Gas in the Galaxy. II. Physical State of "CO-dark" Gas in the Perseus Arm

We report the results from a new, highly sensitive (ΔTmb ∼ 3 mK) survey for thermal OH emission at 1665 and 1667 MHz over a dense, 9 × 9 pixel grid covering a 1° × 1° patch of sky in the direction of l = 105 00, b = +2 50 toward the Perseus spiral arm of our Galaxy. We compare our Green Bank Telesco...

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Bibliographic Details
Published in:The Astrophysical journal Vol. 883; no. 2; pp. 158 - 167
Main Authors: Busch, Michael P., Allen, Ronald J., Engelke, Philip D., Hogg, David E., Neufeld, David A., Wolfire, Mark G.
Format: Journal Article
Language:English
Published: Philadelphia The American Astronomical Society 01-10-2019
IOP Publishing
Subjects:
Astronomy
Astrophysics
Cloud models
Density
Emission
Galactic structure
Galaxies
Galaxy: disk
ISM: molecules
ISM: structure
local interstellar matter
Milky Way
Molecular clouds
Molecular gases
Molecular structure
Polls & surveys
Radio astronomy
radio lines: ISM
Sensitivity
Stars & galaxies
surveys
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Summary:We report the results from a new, highly sensitive (ΔTmb ∼ 3 mK) survey for thermal OH emission at 1665 and 1667 MHz over a dense, 9 × 9 pixel grid covering a 1° × 1° patch of sky in the direction of l = 105 00, b = +2 50 toward the Perseus spiral arm of our Galaxy. We compare our Green Bank Telescope 1667 MHz OH results with archival 12CO(1-0) observations from the Five College Radio Astronomy Observatory Outer Galaxy Survey within the velocity range of the Perseus Arm at these galactic coordinates. Out of the 81 statistically independent pointings in our survey area, 86% show detectable OH emission at 1667 MHz, and 19% of them show detectable CO emission. We explore the possible physical conditions of the observed features using a set of diffuse molecular cloud models. In the context of these models, both OH and CO disappear at current sensitivity limits below an Av of 0.2, but the CO emission does not appear until the volume density exceeds 100-200 . These results demonstrate that a combination of low column density Av and low volume density nH can explain the lack of CO emission along sight lines exhibiting OH emission. The 18 cm OH main lines, with their low critical density of n* ∼ 1 , are collisionally excited over a large fraction of the quiescent galactic environment and, for observations of sufficient sensitivity, provide an optically thin radio tracer for diffuse H2.
Bibliography:AAS17851
Interstellar Matter and the Local Universe
ISSN:0004-637X
1538-4357
1538-4357
DOI:10.3847/1538-4357/ab3a4b