Characterizing [C II] line emission in massive star-forming clumps

Jackson, James M.; Allingham, David; Killerby-Smith, Nicholas; Whitaker, J. Scott; Smith, Howard A.; Contreras, Yanett; Guzman, Andrés E.; Hogge, Taylor; Sanhueza, Patricio; Stephens, Ian W.

Title: Characterizing [C II] line emission in massive star-forming clumps
Creator: Jackson, James M.; Allingham, David; Killerby-Smith, Nicholas; Whitaker, J. Scott; Smith, Howard A.; Contreras, Yanett; Guzman, Andrés E.; Hogge, Taylor; Sanhueza, Patricio; Stephens, Ian W.
Relation: Astrophysical Journal Vol. 904, Issue 1, no. 18
Publisher Link: http://dx.doi.org/10.3847/1538-4357/abba2e
Publisher: Institute of Physics (IOP)
Resource Type: journal article
Date: 2020
Description: Because the 157.74 μm [C II] line is the dominant coolant of star-forming regions, it is often used to infer the global star formation rates of galaxies. By characterizing the [C II] and far-infrared emission from nearby Galactic star-forming molecular clumps, it is possible to determine whether extragalactic [C II] emission arises from a large ensemble of such clumps, and whether [C II] is indeed a robust indicator of global star formation. We describe [C II] and far-infrared observations using the FIFI-LS instrument on the Stratospheric Observatory For Infrared Astronomy (SOFIA) airborne observatory toward four dense, high-mass, Milky Way clumps. Despite similar farinfrared luminosities, the [C II] to far-infrared luminosity ratio, L_{[C II]}/L_FIR, varies by a factor of at least 140 among these four clumps. In particular, for AGAL313.576+0.324, no [C II] line emission is detected despite a FIR luminosity of 24,000 L. AGAL313.576+0.324 lies a factor of more than 100 below the empirical correlation curve between L_{[C II]}/L_FIR and S_v (63 μm) S_v (158 μm) found for galaxies. AGAL313.576+0.324 may be in an early evolutionary “protostellar” phase with insufficient ultraviolet flux to ionize carbon, or in a deeply embedded “‘hypercompact” H II region phase where dust attenuation of UV flux limits the region of ionized carbon to undetectably small volumes. Alternatively, its apparent lack of [C II] emission may arise from deep absorption of the [C II] line against the 158 μm continuum, or self-absorption of brighter line emission by foreground material, which might cancel or diminish any emission within the FIFI-LS instrument’s broad spectral resolution element (AV ~ 250 km s⁻¹).
Subject: global star formation; galaxies; far-infrared obervations; astronomy
Identifier: http://hdl.handle.net/1959.13/1428041
Identifier: uon:38595
Identifier: ISSN:0004-637X
Language: eng
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