Cloud formation in the atomic and molecular phase: H I self absorption (HISA) towards a giant molecular filament

Wang, Y.; Bihr, S.; Beuther, H.; Rugel, M.; Soler, J. D.; Ott, J.; Kainulainen, J.; Schneider, N.; Klessen, Ralf S.; Glover, Simon C. O.; McClure-Griffiths, N. M.; Goldsmith, Paul F.; Johnston, K. G.; Menten, K. M.; Ragan, S. E.; Urquhart, J. S.; Linz, H.; Roy, Nirupam; Smith, Rowan J.; Bigiel, Frank; Henning, Thomas; Longmore, Steven N.

doi:10.1051/0004-6361/201935866

Cited by 36 publications

(79 citation statements)

References 128 publications

(184 reference statements)

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“…Riener et al (2020) estimated the 13 CO(1-0) optical depth for GMF24, and found a median τ value of ∼0.5. Wang et al (2020) found that the GRS 13 CO(1-0) optical depth for another filament, GMF38a (l ∼ 33 • −37 • ), is mostly smaller than 1 with a median value of ∼0.4. If we apply this 0.4 to GMF54, the column density increases by ∼21%.…”

Section: Uncertaintiesmentioning

confidence: 91%

“…The 13 CO N-PDF can be better described with a log-normal function, but we still could not recover the log-normal peak of the N-PDFs. Wang et al (2020) studied the N-PDFs of the atomic and molecular gas in the giant molecular filament GMF38a, and found that the N-PDF of H I emission has the smallest width, followed by the cold neutral media traced by H I self absorption (HISA), and the 13 CO N-PDF has the largest width. It seems that the width of the N-PDF is correlated with the density it traces.…”

Section: N-pdfs Of the Whole Filamentmentioning

confidence: 99%

“…Studies of nearby molecular clouds (MCs) show that the dense regions of MCs are permeated with filaments that contain sites of star formation (e.g., André et al 2014). Recent observations identified a class of large ( 50 pc) and massive ( 10 5 M ) filaments, known as giant molecular filaments (GMFs;Jackson et al 2010;Goodman et al 2014;Ragan et al 2014;Zucker et al 2015;Wang et al 2015Wang et al , 2016Wang et al , 2020Li et al 2016;Abreu-Vicente et al 2016). Many of these giant filaments lie along, or extremely close to spiral arms in the position-position-velocity space, suggesting they may trace the dense "spine" of the spiral arms and the mid-plane of the gravitational potential in the Milky Way (MW; Goodman et al 2014;Zucker et al 2015).…”

Section: Introductionmentioning

confidence: 99%

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Dense gas in a giant molecular filament

Wang

Beuther

Schneider

et al. 2020

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Context. Recent surveys of the Galactic plane in the dust continuum and CO emission lines reveal that large (≳50 pc) and massive (≳105 M⊙) filaments, know as giant molecular filaments (GMFs), may be linked to Galactic dynamics and trace the mid-plane of the gravitational potential in the Milky Way. Yet our physical understanding of GMFs is still poor. Aims. We investigate the dense gas properties of one GMF, with the ultimate goal of connecting these dense gas tracers with star formation processes in the GMF. Methods. We imaged one entire GMF located at l ~ 52–54° longitude, GMF54 (~68 pc long), in the empirical dense gas tracers using the HCN(1–0), HNC(1–0), and HCO+(1–0) lines, and their 13C isotopologue transitions, as well as the N2H+(1–0) line. We studied the dense gas distribution, the column density probability density functions (N-PDFs), and the line ratios within the GMF. Results. The dense gas molecular transitions follow the extended structure of the filament with area filling factors between 0.06 and 0.28 with respect to 13CO(1–0). We constructed the N-PDFs of H2 for each of the dense gas tracers based on their column densities and assumed uniform abundance. The N-PDFs of the dense gas tracers appear curved in log–log representation, and the HCO+ N-PDF has the flattest power-law slope index. Studying the N-PDFs for sub-regions of GMF54, we found an evolutionary trend in the N-PDFs that high-mass star-forming and photon-dominated regions have flatter power-law indices. The integrated intensity ratios of the molecular lines in GMF54 are comparable to those in nearby galaxies. In particular, the N2H+/13CO ratio, which traces the dense gas fraction, has similar values in GMF54 and all nearby galaxies except Ultraluminous Infrared Galaxies. Conclusions. As the largest coherent cold gaseous structure in our Milky Way, GMFs, are outstanding candidates for connecting studies of star formation on Galactic and extragalactic scales. By analyzing a complete map of the dense gas in a GMF we have found that: (1) the dense gas N-PDFs appear flatter in more evolved regions and steeper in younger regions, and (2) its integrated dense gas intensity ratios are similar to those of nearby galaxies.

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Section: Uncertaintiesmentioning

confidence: 91%

Section: N-pdfs Of the Whole Filamentmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Dense gas in a giant molecular filament

Wang

Beuther

Schneider

et al. 2020

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“…The 13 CO emission peaks at different velocities are not associated with GMF20.0-17.9 as their velocities are attributed to neighboring spiral arm structures (e.g., Vallée 2008;Reid et al 2014Reid et al , 2019. For the analysis of the physical properties of HISA, we followed the derivation by Gibson et al (2000) and Wang et al (2020a). A comprehensive discussion of the radiative transfer of HISA clouds is given in Gibson et al (2000), Kavars et al (2003), and Li & Goldsmith (2003).…”

Section: H I Self-absorption (Hisa) Extractionmentioning

confidence: 99%

“…Observations of H I 21cm line A68, page 1 of 21 A&A 642, A68 (2020) emission are generally attributed to both warm neutral medium (WNM) and CNM. To separate the WNM from the CNM, we make use of the presence of H I self-absorption (HISA; see e.g., Riegel & Crutcher 1972;Knapp 1974;van der Werf et al 1988;Feldt 1993;Gibson et al 2000Gibson et al , 2005aKavars et al 2003;Dénes et al 2018;Wang et al 2020a) to trace the cold atomic phase. H I self-absorption is found throughout the Milky Way in various environments.…”

Section: Introductionmentioning

confidence: 99%

Atomic and molecular gas properties during cloud formation

Syed

Wang

Beuther

et al. 2020

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Context. Molecular clouds, which harbor the birthplaces of stars, form out of the atomic phase of the interstellar medium (ISM). To understand this transition process, it is crucial to investigate the spatial and kinematic relationships between atomic and molecular gas. Aims. We aim to characterize the atomic and molecular phases of the ISM and set their physical properties into the context of cloud formation processes. Methods. We studied the cold neutral medium (CNM) by means of H I self-absorption (HISA) toward the giant molecular filament GMF20.0-17.9 (distance = 3.5 kpc, length ~170 pc) and compared our results with molecular gas traced by 13CO emission. We fitted baselines of HISA features to H I emission spectra using first and second order polynomial functions. Results. The CNM identified by this method spatially correlates with the morphology of the molecular gas toward the western region. However, no spatial correlation between HISA and 13CO is evident toward the eastern part of the filament. The distribution of HISA peak velocities and line widths agrees well with 13CO within the whole filament. The column densities of the CNM probed by HISA are on the order of 1020 cm−2 while those of molecular hydrogen traced by 13CO are an order of magnitude higher. The column density probability density functions (N-PDFs) of HISA (CNM) and H I emission (tracing both the CNM and the warm neutral medium, WNM) have a log-normal shape for all parts of the filament, indicative of turbulent motions as the main driver for these structures. The H2 N-PDFs show a broad log-normal distribution with a power-law tail suggesting the onset of gravitational contraction. The saturation of H I column density is observed at ~25 M⊙ pc−2. Conclusions. We conjecture that different evolutionary stages are evident within the filament. In the eastern region, we witness the onset of molecular cloud formation out of the atomic gas reservoir while the western part is more evolved, as it reveals pronounced H2 column density peaks and signs of active star formation.

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