A population of hypercompact H II regions identified from young H II regions

Yang, A. Y.; Urquhart, J. S.; Menten, K. M.; Wyrowski, F.; Brunthaler, A.; Wu, Tian; Rugel, M.; Yang, Xiaolong; Yao, Shujie; Mutale, M.

doi:10.1051/0004-6361/202038608

Cited by 23 publications

(21 citation statements)

References 133 publications

(344 reference statements)

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“…Emission measure is a function of the average electron number density (n e ) and path length (L) through plasma: EM = n 2 e × L. Assuming the path length (L) is the same with the source size (we assume each component of J1146+4037 has a size of 2.5 pc), we calculate the electron number density n e of 1.22 +0.11 −0.11 × 10 4 , 1.58 +0.26 −0.24 × 10 4 , and 3.59 +3.88 −2.12 × 10 4 cm −3 for J0131−0321 and the two components of J1146+4037, respectively. The derived electron number densities are consistent with that (a mean n e of 1.6 × 10 4 cm −3 ) of a sample of 114 young H ii regions in the Galaxy (Yang et al 2021). The n e can be up to 10 5 cm −3 for hyper-compact H ii regions (e.g., Murphy et al 2010b).…”

Section: Physical Properties Of the Absorbing Mediumsupporting

confidence: 84%

The radio spectral turnover of radio-loud quasars at $z>5$

Shao,

Wagg,

Wang

et al. 2021

Preprint

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We present Karl G. Jansky Very Large Array (VLA) S-(2-4 GHz), C-(4-8 GHz), and X-band (8-12 GHz) continuum observations toward seven radio-loud quasars at z > 5. This sample has previously been found to exhibit spectral peaks at observed-frame frequencies above ∼1 GHz. We also present upgraded Giant Metrewave Radio Telescope (uGMRT) band-2 (200 MHz), band-3 (400 MHz), and band-4 (650 MHz) radio continuum observations toward eight radio-loud quasars at z > 5, selected from our previous GMRT survey, in order to sample their low-frequency synchrotron emission. Combined with archival radio continuum observations, all ten targets show evidence for spectral turnover. The turnover frequencies are ∼1-50 GHz in the rest frame, making these targets gigahertzpeaked-spectrum (GPS) or high-frequency-peaker (HFP) candidates. For the nine well-constrained targets with observations on both sides of the spectral turnover, we fit the entire radio spectrum with absorption models associated with synchrotron self-absorption and free-free absorption (FFA). Our results show that FFA in an external inhomogeneous medium can accurately describe the observed spectra for all nine targets, which may indicate an FFA origin for the radio spectral turnover in our sample. As for the complex spectrum of J114657.79+403708.6 at z = 5.00 with two spectral peaks, it may be caused by multiple components (i.e., core-jet) and FFA by the high-density medium in the nuclear region. However, we cannot rule out the spectral turnover origin of variability. Based on our radio spectral modeling, we calculate the radio loudness R 2500 Å for our sample, which ranges from 12 +1 −1 to 674 +61 −51 .

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Section: Physical Properties Of the Absorbing Mediumsupporting

confidence: 84%

The radio spectral turnover of radio-loud quasars at $z>5$

Shao,

Wagg,

Wang

et al. 2021

Preprint

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“…The outflow wing detection rate in UC H ii regions can be as high as 80% (70/87) for clumps associated with UC H ii regions and masers (H 2 O: 39/50; CH 3 OH: 57/69), and it drops to 65% (48/74) for clumps with UC H ii regions without any maser emission. The detection fraction can even rise to 100% (5/5) for clumps associated with hyper-compact (HC) H ii regions (Yang et al 2019(Yang et al , 2021, however, we note that the sample size is small. This suggests that the outflow detection rate appears to peak in the pre-UC H ii stage (i.e., HC H ii regions, maser-associated UC H ii regions), as stated in Paper I, and then it starts to decrease in the late UC H ii regions phase (no-maser-associated UC H ii regions).…”

Section: The Evolutionary Trends Of Outflow Detection Ratesmentioning

confidence: 78%

The SEDIGISM survey: A search for molecular outflows

Yang

Urquhart

Wyrowski

et al. 2022

A&A

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Context. The formation processes of massive stars are still unclear but a picture is emerging involving accretion disks and molecular outflows in what appears to be a scaled-up version of low-mass star formation. A census of outflow activity towards high-mass star-forming clumps in various evolutionary stages has the potential to shed light on high-mass star formation. Aims. We conducted an outflow survey towards ATLASGAL (APEX Telescope Large Area Survey of the Galaxy) clumps, using SEDIGISM (structure, Excitation, and Dynamics of the Inner Galactic InterStellar Medium) data and aimed to obtain a large sample of clumps exhibiting outflow activity in different evolutionary stages. Methods. We identify the high-velocity wings of the 13 CO lines, indicating outflow activity, toward ATLASGAL clumps by (1) extracting the simultaneously observed 13 CO (2 -1) and C 18 O (2 -1) spectra from SEDIGISM, and (2) subtracting Gaussian fits to the scaled C 18 O (core emission) from the 13 CO line after considering opacity broadening. Results. We have detected high-velocity gas towards 1192 clumps out of a total sample of 2052 corresponding to an overall detection rate of 58%. Outflow activity has been detected in the earliest (apparently) quiescent clumps (i.e., 70µm weak), to the most evolved H ii region stages i.e., 8µm bright with tracers of massive star formation. The detection rate increases as a function of evolution (quiescent=51%, protostellar=47%, YSO = 57%, UC H ii regions = 76%). Conclusions. Our sample is the largest outflow sample identified so far. The high-detection rate from this large sample is consistent with the results of similar studies reported in the literature and supports the scenario that outflows are a ubiquitous feature of highmass star formation. The lower detection rate in early evolutionary stages may be due to the fact that outflows in the early stages are weak and difficult to detect. We obtain a statistically significant sample of outflow clumps for every evolutionary stage, especially for outflow clumps in the earliest stage (i.e., 70 µm dark). The detections of outflows in the 70 µm-dark clumps suggest that the absence of 70 µm emission is not a robust indicator of starless/pre-stellar cores.

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Section: The Evolutionary Trends Of Outflow Detection Ratesmentioning

confidence: 79%

The SEDIGISM survey: a search for molecular outflows

Yang,

Urquhart,

Wyrowski

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

Context. The formation processes of massive stars are still unclear, but a picture is emerging involving accretion disks and molecular outflows in what appears to be a scaled-up version of low-mass star formation. A census of outflow activity toward high-mass starforming clumps in various evolutionary stages has the potential to shed light on high-mass star formation. Aims. We conducted an outflow survey toward ATLASGAL (APEX Telescope Large Area Survey of the Galaxy) clumps using SEDIGISM (structure, Excitation, and Dynamics of the Inner Galactic InterStellar Medium) data and aimed to obtain a large sample of clumps exhibiting outflow activity in different evolutionary stages. Methods. We identify the high-velocity wings of the 13 CO lines, which indicate outflow activity, toward ATLASGAL clumps by (1) extracting the simultaneously observed 13 CO (2 -1) and C 18 O (2 -1) spectra from SEDIGISM, and (2) subtracting Gaussian fits to the scaled C 18 O (core emission) from the 13 CO line after considering opacity broadening. Results. We detected high-velocity gas toward 1192 clumps out of a total sample of 2052, corresponding to an overall detection rate of 58%. Outflow activity has been detected in the earliest (apparently) quiescent clumps (i.e., 70µm weak) to the most evolved H ii region stages (i.e., 8µm bright with tracers of massive star formation). The detection rate increases as a function of evolution (quiescent=51%, protostellar=47%, YSO = 57%, UC H ii regions = 76%). Conclusions. Our sample is the largest outflow sample identified so far. The high detection rate from this large sample is consistent with the results of similar studies reported in the literature and supports the scenario that outflows are a ubiquitous feature of highmass star formation. The lower detection rate in early evolutionary stages may be due to the fact that outflows in the early stages are weak and difficult to detect. We obtain a statistically significant sample of outflow clumps for every evolutionary stage, especially for outflow clumps in the earliest stage (i.e., 70 µm dark). The detections of outflows in the 70 µm dark clumps suggest that the absence of 70 µm emission is not a robust indicator of starless and/or pre-stellar cores.

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A population of hypercompact H II regions identified from young H II regions

Cited by 23 publications

References 133 publications

The radio spectral turnover of radio-loud quasars at $z>5$

The radio spectral turnover of radio-loud quasars at $z>5$

The SEDIGISM survey: A search for molecular outflows

The SEDIGISM survey: a search for molecular outflows

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A population of hypercompact H II regions identified from young H II regions

Cited by 23 publications

References 133 publications

The radio spectral turnover of radio-loud quasars at $z>5$

The radio spectral turnover of radio-loud quasars at $z>5$

The SEDIGISM survey: A search for molecular outflows

The SEDIGISM survey: a search for molecular outflows

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A population of hypercompact H II regions identified from young H II regions