Digging into the Interior of Hot Cores with the ALMA (DIHCA). III. The Chemical Link between NH<sub>2</sub>CHO, HNCO, and H<sub>2</sub>CO

Taniguchi, Kotomi; Sanhueza, Patricio; Olguin, Fernando A.; Gorai, Prasanta; Das, Ankan; Nakamura, Fúmitaka; Saito, Masao; Zhang, Qizhou; Lu, Xing; Li, Shanghuo; Chen, Huei-Ru Vivien

doi:10.3847/1538-4357/acca1d

Cited by 9 publications

(2 citation statements)

References 53 publications

(78 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…For the zeroth moment map we used a variable integration window of twice the line FWHM for data over 5σ rms with σ rms = 2.6 mJy beam −1 and the whole velocity range for the remaining pixels, while for first and second moment maps we consider only emission over 5σ rms . To determine the line central velocity, we use a systemic velocity of −47.2 km s −1 (determined from 13 CH 3 CN by Taniguchi et al 2023). As shown in Figure 2(b) this velocity is consistent with the velocity at the position of ALMA1.…”

Section: Resultsmentioning

confidence: 53%

Digging into the Interior of Hot Cores with ALMA: Spiral Accretion into the High-mass Protostellar Core G336.01–0.82

Olguin,

Sanhueza,

Chen

et al. 2023

ApJL

Self Cite

View full text Add to dashboard Cite

We observed the high-mass star-forming core G336.01–0.82 at 1.3 mm and 0.″05 (∼150 au) angular resolution with the Atacama Large Millimeter/submillimeter Array (ALMA) as part of the Digging into the Interior of Hot Cores with ALMA survey. These high-resolution observations reveal two spiral streamers feeding a circumstellar disk at opposite sides in great detail. Molecular line emission from CH3OH shows velocity gradients along the streamers consistent with infall. Similarly, a flattened envelope model with rotation and infall implies a mass larger than 10 M ☉ for the central source and a centrifugal barrier of 300 au. The location of the centrifugal barrier is consistent with local peaks in the continuum emission. We argue that gas brought by the spiral streamers is accumulating at the centrifugal barrier, which can result in future accretion burst events. A total high infall rate of ∼4 × 10−4 M ☉ yr−1 is derived by matching models to the observed velocity gradient along the streamers. Their contribution accounts for 20%–50% the global infall rate of the core, indicating streamers play an important role in the formation of high-mass stars.

show abstract

Section: Resultsmentioning

confidence: 53%

Digging into the Interior of Hot Cores with ALMA: Spiral Accretion into the High-mass Protostellar Core G336.01–0.82

Olguin,

Sanhueza,

Chen

et al. 2023

ApJL

Self Cite

View full text Add to dashboard Cite

show abstract

“…The spectral resolution is better than that of the two wide-band SPWs (SPWs 7 and 8) of the ATOMS survey, ∼1.6 km s −1 (Liu et al 2020a). The velocity resolution of the QUARKS survey is high enough to spectrally resolve the emission lines of the outflows and ionized gas whose line wings or line widths are typically larger than 10 km s −1 (Liu et al 2021a(Liu et al , 2022cZhang et al 2022), and the emission of complex organic molecules (COMs) from hot cores (ΔV ∼ 5 km s −1 ; Qin et al 2022;Taniguchi et al 2023). The velocity gradients along the longest branches of HFSs were systematically revealed in the ATOMS survey to be 8.7 km s −1 pc −1 on average (Zhou et al 2022), corresponding to a velocity difference of ∼5 km s −1 at the maximum recovering scale (0.6 pc at a distance of 5 kpc) of the QUARKS survey.…”

Section: Alma Observationsmentioning

confidence: 99%

The ALMA-QUARKS Survey. I. Survey Description and Data Reduction

Liu 刘,

Liu,

Zhu

et al. 2024

Res. Astron. Astrophys.

Self Cite

View full text Add to dashboard Cite

This paper presents an overview of the QUARKS survey, which stands for 'Querying Underlying mechanisms of massive star formation with ALMA-Resolved gas Kinematics and Structures'. The QUARKS survey is observing 139 massive gas clumps covered by 156 pointings at ALMA Band 6 (λ~1.3 mm). In conjunction with data obtained from the ALMA-ATOMS survey at Band 3 (λ~3 mm), QUARKS aims to carry out an unbiased statistical investigation of massive star formation process within protoclusters down to a scale of 1000 au. This overview paper describes the observations and data reduction of the QUARKS survey, and gives a first look at an exemplar source, the mini-starburst Sgr B2(M). The wide-bandwidth (7.5 GHz) and high-resolution (~0.3 arcsec) observations of the QUARKS survey allow to resolve much more compact cores than could be done by the ATOMS survey, and to detect fainter filamentary structures that were not revealed earlier. The spectral windows cover transitions of species including CO, SO, N2D+, SiO, H30α, H2CO, CH3CN and many other complex organic molecules, tracing gas components with different temperatures and spatial extents. QUARKS aims to deepen our understanding of several scientific topics of massive star formation, such as mass transport within protoclusters by (hub-)filamentary structures, the existence of massive starless cores, the physical and chemical properties of dense cores within protoclusters, and the feedback from already formed high-mass young protostars.

show abstract

Observations of high-order multiplicity in a high-mass stellar protocluster

Li,

Sanhueza,

Beuther

et al. 2024

Nat Astron

View full text Add to dashboard Cite

The dominant mechanism forming multiple stellar systems in the high-mass regime (M* ≳ 8 M⊙) remained unknown because direct imaging of multiple protostellar systems at early phases of high-mass star formation is very challenging. High-mass stars are expected to form in clustered environments containing binaries and higher-order multiplicity systems. So far only a few high-mass protobinary systems, and no definitive higher-order multiples, have been detected. Here we report the discovery of one quintuple, one quadruple, one triple and four binary protostellar systems simultaneously forming in a single high-mass protocluster, G333.23–0.06, using Atacama Large Millimeter/submillimeter Array high-resolution observations. We present a new example of a group of gravitationally bound binary and higher-order multiples during their early formation phases in a protocluster. This provides the clearest direct measurement of the initial configuration of primordial high-order multiple systems, with implications for the in situ multiplicity and its origin. We find that the binary and higher-order multiple systems, and their parent cores, show no obvious sign of disk-like kinematic structure. We conclude that the observed fragmentation into binary and higher-order multiple systems can be explained by core fragmentation, indicating its crucial role in establishing the multiplicity during high-mass star cluster formation.

show abstract

Digging into the Interior of Hot Cores with the ALMA (DIHCA). III. The Chemical Link between NH₂CHO, HNCO, and H₂CO

Cited by 9 publications

References 53 publications

Digging into the Interior of Hot Cores with ALMA: Spiral Accretion into the High-mass Protostellar Core G336.01–0.82

Digging into the Interior of Hot Cores with ALMA: Spiral Accretion into the High-mass Protostellar Core G336.01–0.82

The ALMA-QUARKS Survey. I. Survey Description and Data Reduction

Observations of high-order multiplicity in a high-mass stellar protocluster

Contact Info

Product

Resources

About

Digging into the Interior of Hot Cores with the ALMA (DIHCA). III. The Chemical Link between NH2CHO, HNCO, and H2CO

Cited by 9 publications

References 53 publications

Digging into the Interior of Hot Cores with ALMA: Spiral Accretion into the High-mass Protostellar Core G336.01–0.82

Digging into the Interior of Hot Cores with ALMA: Spiral Accretion into the High-mass Protostellar Core G336.01–0.82

The ALMA-QUARKS Survey. I. Survey Description and Data Reduction

Observations of high-order multiplicity in a high-mass stellar protocluster

Contact Info

Product

Resources

About

Digging into the Interior of Hot Cores with the ALMA (DIHCA). III. The Chemical Link between NH₂CHO, HNCO, and H₂CO