Interstellar Cloud Conditions Based on 63 μm [O i] Emission and Absorption in W3

We investigate the origin of self-absorption in [O i ] 63 μ m line emission, which is very clearly seen in approximately half of the 12 Galactic giant molecular cloud (GMC)/H ii regions observed. For this study, we observed velocity-resolved spectra of photon-dominated region (PDR) and H ii region t...

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Bibliographic Details
Published in:The Astrophysical journal 2021-07, Vol.916 (1), p.6
Main Authors: Goldsmith, Paul. F., Langer, William D., Seo, Youngmin, Pineda, Jorge, Stutzki, Jürgen, Guevara, Christian, Aladro, Rebeca, Justen, Matthias
Format: Article
Language:English
Subjects:
Absorption
Astrochemistry
Astronomy
Astrophysics
Atomic oxygen
Columnar structure
Dark interstellar clouds
Dense interstellar clouds
Density
Emission analysis
Excitation
H II regions
Infrared astronomy
Interstellar clouds
Interstellar matter
Line shape
Massive stars
Molecular clouds
Oxygen
Star & galaxy formation
Star formation
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Summary:We investigate the origin of self-absorption in [O i ] 63 μ m line emission, which is very clearly seen in approximately half of the 12 Galactic giant molecular cloud (GMC)/H ii regions observed. For this study, we observed velocity-resolved spectra of photon-dominated region (PDR) and H ii region tracers, the [O i ] 63 μ m, [N ii ] 205 μ m, and CO J   =  5–4 and 8–7 lines, with the upGREAT instrument in the 4GREAT configuration on the NASA/DLR Stratospheric Observatory For Infrared Astronomy (SOFIA). To probe the origin of the [O i ] absorption and line shape and what they tell us about the physical conditions, we focus on the W3 region, for which we obtained data for eight positions along a line near the H ii region W3 A. We derive the foreground column density of low-excitation atomic oxygen to be in the range 2–7 × 10 18 cm − 2 . At the position of strongest [O i ] emission and greatest absorbing column density, 24% of the oxygen in the PDR is in the form of low-excitation atomic oxygen. We employ the Meudon PDR code to study the chemical and thermal structure of the PDR and to understand the large column density of neutral oxygen throughout the PDR. The reduction in the integrated intensity of the [O i ] 63 μ m emission is a factor of ≃2–4 in directions with strong [O i ] emission. The results from our sample, if general, would significantly impact the use of the [O i ] 63 μ m line as a tracer of massive star formation and could play a significant role in explaining the “63 μ m [O i ] deficit” seen in very luminous extragalactic sources.
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/abfb69