Search for high-mass protostars with ALMA revealed up to kilo-parsec scales (SPARKS)

Csengeri, T.; Беллоче, А.; Bontemps, Sylvain; Wyrowski, F.; Menten, K. M.; Bouscasse, L.

doi:10.1051/0004-6361/201935226

Cited by 69 publications

(103 citation statements)

References 79 publications

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“…This has been found also by Fontani et al (2007) in hot cores, whereas other authors noticed differences between O-and N-bearing COMs in both the spatial distribution (e.g. Liu 2005;Csengeri et al 2019) and the radial velocities (Blake et al 1987). We also note that, given the increasing abundance trend, molecular destruction routes seem to be less efficient than formation/desorption mechanisms, especially at later evolutionary stages (i.e.…”

Section: Implications For the Chemistry Of Comssupporting

confidence: 73%

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Evolutionary study of complex organic molecules in high-mass star-forming regions

Coletta

Fontani

Rivilla

et al. 2020

A&A

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We have studied four complex organic molecules (COMs), the oxygen-bearing methyl formate (CH3OCHO) and dimethyl ether (CH3OCH3) as well as the nitrogen-bearing formamide (NH2CHO) and ethyl cyanide (C2H5CN), towards a large sample of 39 high-mass star-forming regions representing different evolutionary stages, from early to evolved phases. We aim to identify potential correlations and chemical links between the molecules and to trace their evolutionary sequence through the star formation process. We analysed spectra obtained at 3, 2, and 0.9 mm with the IRAM-30m telescope. We derived the main physical parameters for each species by fitting the molecular lines. We compared them and evaluated their evolution while also taking several other interstellar environments into account. We report detections in 20 sources, revealing a clear dust absorption effect on column densities. Derived abundances range between ~ 10−10−10−7 for CH3OCHO and CH3OCH3, ~ 10−12−10−10 for NH2CHO, and ~ 10−11−10−9 for C2H5CN. The abundances of CH3OCHO, CH3OCH3, and C2H5CN are very strongly correlated (r ≥ 0.92) across ~ 4 orders of magnitude. We note that CH3OCHO and CH3OCH3 show the strongest correlations in most parameters, and a nearly constant ratio (~ 1) over a remarkable ~ 9 orders of magnitude in luminosity for the following wide variety of sources: pre-stellar to evolved cores, low- to high-mass objects, shocks, Galactic clouds, and comets. This indicates that COMs chemistry is likely early developed and then preserved through evolved phases. Moreover, the molecular abundances clearly increase with evolution, covering ~ 6 orders of magnitude in the luminosity/mass ratio. We consider CH3OCHO and CH3OCH3 to be most likely chemically linked. They could, for example, share a common precursor, or be formed one from the other. Based on correlations, ratios, and the evolutionary trend, we propose a general scenario for all COMs, involving a formation in the cold, earliest phases of star formation and a following increasing desorption with the progressive thermal and shock-induced heating of the evolving core.

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Section: Implications For the Chemistry Of Comssupporting

confidence: 73%

“…Moreover, interferometric observations (e.g. Sutton et al 1995;Blake et al 1996;Wyrowski et al 1999;Liu 2005) suggest that O-and N-bearing molecules trace different portions of a molecular star-forming clump (see also Csengeri et al 2019 and references therein). However, several details are still unclear.…”

Section: Introductionmentioning

confidence: 99%

Evolutionary study of complex organic molecules in high-mass star-forming regions

Coletta

Fontani

Rivilla

et al. 2020

A&A

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“…More recently, a large sample including 18 well-known high-mass star-forming regions was observed by the NOEMA with same spectral setup, suggesting that most molecules are destroyed in evolved cores having less emission lines (Gieser et al 2021). Of the detected hot cores, a few show chemical differentiation between nitrogen-and oxygen-bearing COMs (e.g., Wyrowski et al 1999;Qin et al 2010Qin et al , 2015Remijan et al 2004;Kalenskii & Johansson 2010;Suzuki et al 2018;Lee et al 2019;Csengeri et al 2019;Allen et al 2017;Jiménez-Serra et al 2012;Gieser et al 2019;Mills et al 2018). Chemical differentiation and heating mechanism are still longstanding problems due to a lack of large sample and systematic observations.…”

Section: Introductionmentioning

confidence: 95%

“…Due to small source sizes of hot cores, single dish observations suffer from beam dilution and sample the emission from both hot cores and surrounding cold envelopes. The millimeter/submillimeter interferometric arrays (e.g., SMA, NOEMA, and ALMA) offer larger bandwidth, higher spatial resolution and increased sensitivity, which have promoted the hot core observations greatly, but mainly focused on individual sources or small samples (Law et al 2021;van der Walt et al 2021;Beuther et al 2009;Qin et al 2008Qin et al , 2010Qin et al , 2015Rong et al 2016;Rivilla et al 2017;Bøgelund et al 2019;Guzmán et al 2018;Luo et al 2009;Csengeri et al 2019;Sakai et al 2013Sakai et al , 2018Zapata et al 2011;Mottram et al 2020;Fuente et al 2021;Belloche et al 2016Belloche et al , 2019Brogan et al 2016;Bonfand et al 2017;Xue et al 2019;wong & An 2018;Sánchez-Monge et al 2010Hernández-Hernández et al 2014;Peng et al 2019;Liu et al 2001Liu et al , 2002Remijan et al 2003Remijan et al , 2004Palau et al 2017;Wu et al 2014;Taniguchi et al 2020;Rathborne et al 2011;Orozco-Aguilera et al 2017;Ahmadi et al 2018;Mottram et al 2020;Pagani et al 2017;…”

Section: Introductionmentioning

confidence: 99%

ATOMS: ALMA Three-millimeter Observations of Massive Star-forming regions -- VIII. A search for hot cores by using C$_2$H$_5$CN, CH$_3$OCHO and CH$_3$OH lines

Qin,

Liu,

Liu

et al. 2022

Preprint

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Hot cores characterized by rich lines of complex organic molecules are considered as ideal sites for investigating the physical and chemical environments of massive star formation. We present a search for hot cores by using typical nitrogen-and oxygenbearing complex organic molecules (C 2 H 5 CN, CH 3 OCHO and CH 3 OH), based on ALMA Three-millimeter Observations of Massive Star-forming regions (ATOMS). The angular resolutions and line sensitivities of the ALMA observations are better than 2 arcsec and 10 mJy/beam, respectively. A total of 60 hot cores are identified with 45 being newly detected, in which the complex organic molecules have high gas temperatures (> 100 K) and small source sizes (< 0.1 pc). So far this is the largest sample of hot cores observed with similar angular resolution and spectral coverage. The observations have also shown nitrogen and oxygen differentiation in both line emission and gas distribution in 29 hot cores. Column densities of CH 3 OH and CH 3 OCHO increase as rotation temperatures rise. The column density of CH 3 OCHO correlates tightly with that of CH 3 OH. The pathways for production of different species are discussed. Based on the spatial position difference between hot cores and UC HII regions, we conclude that 24 hot cores are externally heated while the other hot cores are internally heated. The observations presented here will potentially help establish a hot core template for studying massive star formation and astrochemistry.

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“…In particular, Complex Organic Molecules (COMs), which consist of more than six atoms with one carbon atom at least, are found to be widely present in various environments of star formation: quiescent dense clouds, prestellar cores (e.g., Bacmann et al 2012;Cernicharo et al 2012;Ceccarelli et al 2017;Soma et al 2018;Scibelli & Shirley 2020), disk/envelope systems of protostellar cores (e.g., Cazaux et al 2003;Bottinelli et al 2004b;Kuan et al 2004;Pineda et al 2012;Jørgensen et al 2016;Oya et al 2016;Lee et al 2019;Imai et al 2019;Bianchi et al 2020), and outflow shock regions around protostars (e.g., Arce et al 2008;Sugimura et al 2011;Codella et al 2020;De Simone et al 2020). Many observations of COMs toward various sources reveal a chemical differentiation between nitrogen-bearing and oxygen-bearing COMs (e.g., Wyrowski et al 1999;Bottinelli et al 2004b;Kuan et al 2004;Beuther et al 2005;Fontani et al 2007;Calcutt et al 2018;Oya et al 2018;Csengeri et al 2019). These re-was evaluated to be between 75 • and 90 • (0 • for a pole-on configuration) with the ALMA observations of the CS and CCH line emission by Oya et al (2018), which confirms the nearly edge-on configuration of the disk/envelope system.…”

Section: Introductionmentioning

confidence: 99%

Molecular Distributions of the Disk/Envelope System of L483: Principal Component Analysis for the Image Cube Data

Okoda,

Oya,

Abe

et al. 2021

Preprint

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Unbiased understandings of molecular distributions in a disk/envelope system of a low-mass protostellar source are crucial for investigating physical and chemical evolution processes. We have observed 23 molecular lines toward the Class 0 protostellar source L483 with ALMA and have performed principal component analysis (PCA) for their cube data (PCA-3D) to characterize their distributions and velocity structures in the vicinity of the protostar. The sum of the contributions of the first three components is 63.1%. Most oxygen-bearing complex-organic-molecule lines have a large correlation with the first principal component (PC1), representing the overall structure of the disk/envelope system around the protostar. Contrary, the C 18 O and SiO emissions show small and negative correlations with PC1. The NH 2 CHO lines stand out conspicuously at the second principal component (PC2), revealing more compact distribution. The HNCO lines and the high excitation line of CH 3 OH have a similar trend for PC2 to NH 2 CHO. On the other hand, C 18 O is well correlated with the third principal component (PC3). Thus, PCA-3D enables us to elucidate the similarities and the differences of the distributions and the velocity structures among molecular lines simultaneously, so that the chemical differentiation between the oxygen-bearing complex organic molecules and the nitrogen-bearing ones is revealed in this source. We have also conducted PCA for the moment 0 maps (PCA-2D) and that for the spectral line profiles (PCA-1D). While they can extract part of characteristics of the molecular-line data, PCA-3D is essential for comprehensive understandings. Characteristic features of the molecular-line distributions are discussed on NH 2 CHO.

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Search for high-mass protostars with ALMA revealed up to kilo-parsec scales (SPARKS)

Cited by 69 publications

References 79 publications

Evolutionary study of complex organic molecules in high-mass star-forming regions

Evolutionary study of complex organic molecules in high-mass star-forming regions

ATOMS: ALMA Three-millimeter Observations of Massive Star-forming regions -- VIII. A search for hot cores by using C$_2$H$_5$CN, CH$_3$OCHO and CH$_3$OH lines

Molecular Distributions of the Disk/Envelope System of L483: Principal Component Analysis for the Image Cube Data

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