LMC-N11 (LHA 120-N11) [CII], HI, CO spectra Virtual Observatory Resource

Authors
  1. Lebouteiller V.
  2. Cormier D.
  3. Madden S.C.
  4. Galametz M.
  5. Hony S.
  6. Galliano F.,Chevance M.
  7. Lee M.-Y.
  8. Braine J.
  9. Polles F.L.
  10. Requena-Torres M.A.,Indebetouw R.
  11. Hughes A.
  12. Abel N.
  13. Published by
    CDS
Abstract

The ambiguous origin of the [CII] 158um line in the interstellar medium complicates its use for diagnostics concerning the star-formation rate and physical conditions in photodissociation regions. We investigate the origin of [CII] in order to measure the total molecular gas content, the fraction of CO-dark H_2_ gas, and how these parameters are impacted by environmental effects such as stellar feedback. We observed the giant HII region N 11 in the Large Magellanic Cloud with SOFIA/GREAT. The [CII] line is resolved in velocity and compared to HI and CO, using a Bayesian approach to decompose the line profiles. A simple model accounting for collisions in the neutral atomic and molecular gas was used in order to derive the H_2_ column density traced by C^+^. The profile of [CII] most closely resembles that of CO, but the integrated [CII] line width lies between that of CO and that of HI. Using various methods, we find that [CII] mostly originates from the neutral gas. We show that [CII] mostly traces the CO-dark H_2_ gas but there is evidence of a weak contribution from neutral atomic gas preferentially in the faintest components (as opposed to components with low [CII]/CO or low CO column density). Most of the molecular gas is CO-dark. The CO-dark H_2_ gas, whose density is typically a few 100s/cm^3^ and thermal pressure in the range 10^3.5-5^K/cm^3^, is not always in pressure equilibrium with the neutral atomic gas. The fraction of CO-dark H_2_ gas decreases with increasing CO column density, with a slope that seems to depend on the impinging radiation field from nearby massive stars. Finally we extend previous measurements of the photoelectric-effect heating efficiency, which we find is constant across regions probed with Herschel, with [CII] and [OI] being the main coolants in faint and diffuse, and bright and compact regions, respectively, and with polycyclic aromatic hydrocarbon emission tracing the CO-dark H_2_ gas heating where [CII] and [OI] emit. We present an innovative spectral decomposition method that allows statistical trends to be derived for the molecular gas content using CO, [CII], and HI profiles. Our study highlights the importance of velocity-resolved photodissociation region (PDR) diagnostics and higher spatial resolution for HI observations as future steps.

Keywords
  1. magellanic-clouds
  2. h-ii-regions
  3. co-line-emission
  4. h-i-line-emission
Bibliographic source Bibcode
2019A&A...632A.106L
See also HTML
https://cdsarc.cds.unistra.fr/viz-bin/cat/J/A+A/632/A106
IVOA Identifier IVOID
ivo://CDS.VizieR/J/A+A/632/A106
Document Object Identifer DOI
doi:10.26093/cds/vizier.36320106

Access

Web browser access HTML
http://vizier.cds.unistra.fr/viz-bin/VizieR-2?-source=J/A+A/632/A106
https://vizier.iucaa.in/viz-bin/VizieR-2?-source=J/A+A/632/A106
http://vizieridia.saao.ac.za/viz-bin/VizieR-2?-source=J/A+A/632/A106
IVOA Table Access TAP
http://tapvizier.cds.unistra.fr/TAPVizieR/tap
Run SQL-like queries with TAP-enabled clients (e.g., TOPCAT).

History

2019-12-10T09:49:30Z
Resource record created
2019-12-10T08:52:19Z
Updated
2019-12-10T09:49:30Z
Created

Contact

Name
CDS support team
Postal Address
CDS, Observatoire de Strasbourg, 11 rue de l'Universite, F-67000 Strasbourg, France
E-Mail
cds-question@unistra.fr