New Insights into the H ii Region G18.88–0.49: Hub–Filament System and Accreting Filaments

Dewangan, L. K.; Ojha, D. K.; Sharma, Saurabh; Palacio, Santiago; Bhadari, N. K.; Das, Anirban

doi:10.3847/1538-4357/abb827

Cited by 38 publications

(22 citation statements)

References 86 publications

(125 reference statements)

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“…The color-composite map is also overlaid with the ATLASGAL 870 µm continuum contours, and enables us to visually examine embedded filaments in the direction of G25.4NW or J18354N, which are indicated by solid curves. Based on the observed configuration of the filaments, we find the existence of a "hubfilament" system in G25.4NW (e.g., Myers 2009;Schneider et al 2012;Baug et al 2015;Dewangan et al 2015Dewangan et al , 2018Dewangan et al , 2020.…”

Section: New Candidate Hub-filament System In G254nwmentioning

confidence: 90%

“…Ultimately the global non-isotropic collapse scenario suggests that an infrared-bright massive protostar forms via the inflow from larger scales, and produces an H ii region (in a time of few 10 5 -10 6 yr) through its the stellar UV radiation. Some known sites hosting a hub-filament system are Ophiuchus (Myers 2009), Taurus (Myers 2009), Rosette (Schneider et al 2012), IRDC G14.225−0.506 (Busquet et al 2013), SDC335.579−0.292 (Peretto et al 2013), Sh 2-138 (Baug et al 2015), W42 (Dewangan et al 2015), IRAS 05480+2545 (Dewangan et al 2017b), Sh 2-53 (Baug et al 2018), and Monoceros R2 (Treviño-Morales et al 2019), and G18.88−0.49 (Dewangan et al 2020). More details of the global non-isotropic collapse scenario can be found in Tigé et al (2017); Motte et al (2018) (see also Treviño-Morales et al 2019;Dewangan et al 2020).…”

Section: Discussionmentioning

confidence: 99%

“…In order to further explore the embedded filaments, we processed the Herschel 160 µm image through an edge detection algorithm (i.e. Difference of Gaussian (DoG); see Gonzalez & Woods 2011;Assirati et al 2014;Dewangan et al 2017bDewangan et al , 2020. In Figure 2b, we display a two colorcomposite map made using the Herschel 160 µm image and the DoG processed 160 µm image.…”

Section: New Candidate Hub-filament System In G254nwmentioning

confidence: 99%

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Unraveling the inner substructure of new candidate hub-filament system in the HII region G25.4NW

Dewangan

2021

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We present multi-scale and multi-wavelength data of the Galactic H ii region G25.4-0.14 (hereafter G25.4NW, distance ∼5.7 kpc). The SHARC-II 350 µm continuum map displays a hub-filament configuration containing five parsec scale filaments and a central compact hub. Through the 5 GHz radio continuum map, four ionized clumps (i.e., Ia-Id) are identified toward the central hub, and are powered by massive OBstars. The Herschel temperature map depicts the warm dust emission (i.e., T d ∼23-39 K) toward the hub. High resolution Atacama Large Millimeter/submillimeter Array (ALMA) 1.3 mm continuum map (resolution ∼0. 82 × 0. 58) reveals three cores (c1-c3; mass ∼80-130 M ) toward the ionized clumps Ia, and another one (c4; mass ∼70 M ) toward the ionized clump Ib. A compact near-infrared (NIR) emission feature (extent ∼0.2 pc) is investigated toward the ionized clump Ia excited by an O8V-type star, and contains at least three embedded K-band stars. In the direction of the ionized clump Ia, the ALMA map also shows an elongated feature (extent ∼0.2 pc) hosting the cores c1-c3. All these findings together illustrate the existence of a small cluster of massive stars in the central hub. Considering the detection of the hub-filament morphology and the spatial locations of the mm cores, a global non-isotropic collapse (GNIC) scenario appears to be applicable in G25.4NW, which includes the basic ingredients of the global hierarchical collapse and clump-fed accretion models. Overall, the GNIC scenario explains the birth of massive stars in G25.4NW.

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Section: New Candidate Hub-filament System In G254nwmentioning

confidence: 90%

Section: Discussionmentioning

confidence: 99%

Section: New Candidate Hub-filament System In G254nwmentioning

confidence: 99%

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Unraveling the inner substructure of new candidate hub-filament system in the HII region G25.4NW

Dewangan

2021

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“…These massive stars can further create H ii region/s which can trigger formation of the second generation of stars. In literature, there are multiple examples of H ii regions found in the HFSs (Myers 2009;Deharveng et al 2015;Dewangan et al 2017aDewangan et al , 2020a.…”

Section: Formation Of Massive Stars: Possibility Of Amentioning

confidence: 99%

“…Dale et al (2015) have discussed other star formation processes like cloud-cloud collision, filamentary interactions etc. In recent years many authors have pointed out the active role of filamentary structures and their subsequent interaction in star formation (Schneider et al 2012;Dewangan et al 2017bDewangan et al , 2020a. Filamentary structures are often seen harboring young stellar clusters and massive starforming clumps, yet their precise role in star formation is not very well understood.…”

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confidence: 99%

Sh 2-301: a blistered H II region undergoing star formation

Pandey,

Sharma,

Dewangan

et al. 2021

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We present a multiwavelength study of the H ii region Sh 2-301 (S301) using deep optical data, near-infrared data, radio continuum data and other archival data at longer wavelengths. A cluster of young stellar objects (YSOs) is identified in the north-east (NE) direction of S301. The Hα and radio continuum images trace the distribution of the ionized gas surrounding a massive star ALS 207, and the S301 H ii region is bounded by an arc-like structure of gas and dust emission in the south-eastern direction. The north-western part of S301 seems to be devoid of gas and dust emission, while the presence of molecular material between the NE cluster and the central massive star ALS 207 is found. The distribution of warm dust emission, ionized gas, and neutral hydrogen together suggests a blistered morphology of the S301 H ii region powered by ALS 207, which appears to be located near the edge of the cloud. The location of the NE cluster embedded in the cold molecular cloud is found opposite to the blistered morphology. There is a noticeable age difference investigated between the massive star and the NE cluster. This age difference, pressure calculation, photodissociation regions (PDRs), and the distribution of YSOs favour the positive feedback of the massive star ALS 207 in S301. On a wider scale of S301, the H ii region and the young stellar cluster are depicted toward the central region of a hub-filamentary system, which is evident in the infrared images.

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