Molecular Abundance Variations Among and Within Cold, Dark Molecular Clouds

Chemical considerations and simplified dynamical modeling suggest that dark cloud cores may be incessantly evolving such that the time spent at high core densities decreases as the density increases. After reaching a high density, gravitationally contracting dark cloud cores may either form stars or expand to states of lower densities. Cloud mass and initial density are amongst the factors that may control the evolutionary fate of the core. This view is diametrically opposite of the common belief that dense cores may be in near mechanical equilibrium. Mutually consistent end-to-end modeling of the spectral line profiles and intensities is needed to discern the reality.

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Molecular depletions in cloud cores

Symposium - International Astronomical Union ◽

10.1017/s0074180900009347 ◽

1997 ◽

Vol 178 ◽

pp. 183-192 ◽

Cited By ~ 5

Author(s):

Lee G. Mundy ◽

Joseph P. McMullin

Keyword(s):

Gas Phase ◽

Chemical Evolution ◽

Quantitative Study ◽

Molecular Clouds ◽

Stellar Systems ◽

Gas Phase Molecules ◽

Cloud Cores

The condensation of gas-phase molecules onto grain surfaces in cold molecular clouds is widely expected, and the presence of the resultant icy mantles well established, but quantitative study of the gas-phase depletions has not proved easy. This paper reviews the methods for determining depletions and the associated problems. Further observations are critical to testing our expectations for depletions and for the chemical evolution of forming stellar systems.

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A Dark-Cloud Complex in Aquila: Small Molecular Clouds Possibly Associated with the Aquila Rift

Publications of the Astronomical Society of Japan ◽

10.1093/pasj/51.6.851 ◽

1999 ◽

Vol 51 (6) ◽

pp. 851-858 ◽

Cited By ~ 13

Author(s):

Akiko Kawamura ◽

Toshikazu Onishi ◽

Akira Mizuno ◽

Hideo Ogawa ◽

Yasuo Fukui

Keyword(s):

Molecular Clouds ◽

Velocity Dispersion ◽

Galactic Plane ◽

Dark Cloud ◽

Dark Clouds ◽

Order Of Magnitude ◽

Virial Mass ◽

The Individual ◽

Cloud Complex ◽

Gravitational Equilibrium

Abstract A 12CO(J = 1−0) survey for local molecular clouds was performed toward dark clouds in Aquila (26° < l ≤ 42° and −25° ≤ b < −2°) by using the 4-meter millimeter wave telescope, NANTEN, at Las Campanas Observatory, Chile. A cloud complex consisting of 64 small clouds has been discovered in −25° ≲ b ≲ −12°; at a distance of 220 pc, its height from the galactic plane is ∼ 50–100 pc and the total mass is ∼ 4 × 103M⊙. The spatial and velocity distributions of the complex suggest that it may be connected to the Great Rift in Aquila. This complex, as a whole, has a significantly large virial mass compared with the mass derived from the CO intensities by an order of magnitude, though H I gas of ∼ 104M⊙, possibly associated, may contribute to bind them gravitationally. The individual CO clouds have velocity dispersion and mass similar to those of the high-latitude clouds; also, the clouds are not in gravitational equilibrium. There is no indication of active star formation.

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Evidence for collapse in dark clouds

Symposium - International Astronomical Union ◽

10.1017/s0074180900009359 ◽

1997 ◽

Vol 178 ◽

pp. 193-202

Author(s):

S. Zhou

Keyword(s):

Star Formation ◽

Dark Cloud ◽

Dark Clouds ◽

Bok Globules ◽

Cloud Cores

Bart Bok speculated back in the 1940's that dark cloud cores (i.e. Bok globules) are sites of star formation. The means for probing the dark cloud cores, molecules, were not discovered until much later. Today, we can finally say Bart Bok was right! Evidence for collapse in dark cloud cores will be discussed in general, along with specific examples of collapse candidates. We also describe methods to search for new candidates and the complications in identifying the infall motion.

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Dynamical conditions of dense clumps in dark clouds: a strategy for elucidation

Symposium - International Astronomical Union ◽

10.1017/s0074180900198821 ◽

1991 ◽

Vol 147 ◽

pp. 93-99

Author(s):

Sheo S. Prasad

Keyword(s):

Initial Density ◽

Common Belief ◽

Line Profiles ◽

Dark Cloud ◽

Dark Clouds ◽

The Core ◽

Dense Cores ◽

The Common ◽

Cloud Cores ◽

Evolutionary Fate

Chemical considerations and simplified dynamical modeling suggest that dark cloud cores may be incessantly evolving such that the time spent at high core densities decreases as the density increases. After reaching a high density, gravitationally contracting dark cloud cores may either form stars or expand to states of lower densities. Cloud mass and initial density are amongst the factors that may control the evolutionary fate of the core. This view is diametrically opposite of the common belief that dense cores may be in near mechanical equilibrium. Mutually consistent end-to-end modeling of the spectral line profiles and intensities is needed to discern the reality.

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Magnetic fields and star formation – new observational results

Proceedings of the International Astronomical Union ◽

10.1017/s1743921307001366 ◽

2006 ◽

Vol 2 (S237) ◽

pp. 141-147

Author(s):

Richard M. Crutcher ◽

Thomas H. Troland

Keyword(s):

Magnetic Field ◽

Star Formation ◽

Magnetic Fields ◽

Interstellar Medium ◽

Observational Data ◽

Molecular Clouds ◽

Dark Cloud ◽

Magnetic Field Model ◽

Field Lines ◽

Cloud Cores

AbstractAlthough the subject of this meeting is triggered star formation in a turbulent interstellar medium, it remains unsettled what role magnetic fields play in the star formation process. This paper briefly reviews star formation model predictions for the ratio of mass to magnetic flux, describes how Zeeman observations can test these predictions, describes new results – an extensive OH Zeeman survey of dark cloud cores with the Arecibo telescope, and discusses the implications. Conclusions are that the new data support and extend the conclusions based on the older observational results – that observational data on magnetic fields in molecular clouds are consistent with the strong magnetic field model of star formation. In addition, the observational data on magnetic field strengths in the interstellar medium strongly suggest that molecular clouds must form primarily by accumulation of matter along field lines. Finally, a future observational project is described that could definitively test the ambipolar diffusion model for the formation of cores and hence of stars.

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The formation of glycine and other complex organic molecules in exploding ice mantles

Faraday Discussions ◽

10.1039/c3fd00155e ◽

2014 ◽

Vol 168 ◽

pp. 369-388 ◽

Cited By ~ 6

Author(s):

J. M. C. Rawlings ◽

D. A. Williams ◽

S. Viti ◽

C. Cecchi-Pestellini ◽

W. W. Duley

Keyword(s):

Gas Phase ◽

Molecular Clouds ◽

Organic Molecules ◽

Alternative Mechanism ◽

Hydrogen Atoms ◽

Interstellar Gas ◽

Dark Cloud ◽

Short Period ◽

Molecular Abundances ◽

Complex Organic

Complex Organic Molecules (COMs), such as propylene (CH3CHCH2) and the isomers of C2H4O2 are detected in cold molecular clouds (such as TMC-1) with high fractional abundances (Marcelino et al., Astrophys. J., 2007, 665, L127). The formation mechanism for these species is the subject of intense speculation, as is the possibility of the formation of simple amino acids such as glycine (NH2CH2COOH). At typical dark cloud densities, normal interstellar gas-phase chemistries are inefficient, whilst surface chemistry is at best ill defined and does not easily reproduce the abundance ratios observed in the gas phase. Whatever mechanism(s) is/are operating, it/they must be both efficient at converting a significant fraction of the available carbon budget into COMs, and capable of efficiently returning the COMs to the gas phase. In our previous studies we proposed a complementary, alternative mechanism, in which medium- and large-sized molecules are formed by three-body gas kinetic reactions in the warm high density gas phase. This environment exists, for a very short period of time, after the total sublimation of grain ice mantles in transient co-desorption events. In order to drive the process, rapid and efficient mantle sublimation is required and we have proposed that ice mantle ‘explosions’ can be driven by the catastrophic recombination of trapped hydrogen atoms, and other radicals, in the ice. Repeated cycles of freeze-out and explosion can thus lead to a cumulative molecular enrichment of the interstellar medium. Using existing studies we based our chemical network on simple radical addition, subject to enthalpy and valency restrictions. In this work we have extended the chemistry to include the formation pathways of glycine and other large molecular species that are detected in molecular clouds. We find that the mechanism is capable of explaining the observed molecular abundances and complexity in these sources. We find that the proposed mechanism is easily capable of explaining the large abundances of all three isomers of C2H4O2 that are observationally inferred for star-forming regions. However, the model currently does not provide an obvious explanation for the predominance of methyl formate, suggesting that some refinement to our (very simplistic) chemistry is necessary. The model also predicts the production of glycine at a (lower) abundance level, that is consistent with its marginal detection in astrophysical sources.

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Polarimetric and photometric observations of CB54, with analysis of four other dark clouds

Monthly Notices of the Royal Astronomical Society ◽

10.1093/mnras/stab380 ◽

2021 ◽

Vol 503 (4) ◽

pp. 5274-5290

Author(s):

A K Sen ◽

V B Il’in ◽

M S Prokopjeva ◽

R Gupta

Keyword(s):

Magnetic Field ◽

Near Infrared ◽

Galactic Plane ◽

Photometric Data ◽

Dust Particles ◽

Dark Cloud ◽

Dark Clouds ◽

High Polarization ◽

Field Parallel ◽

Photometric Observations

ABSTRACT We present the results of our BVR-band photometric and R-band polarimetric observations of ∼40 stars in the periphery of the dark cloud CB54. From different photometric data, we estimate E(B − V) and E(J − H). After involving data from other sources, we discuss the extinction variations towards CB54. We reveal two main dust layers: a foreground, E(B − V) ≈ 0.1 mag, at ∼200 pc and an extended layer, $E(B-V) \gtrsim 0.3$ mag, at ∼1.5 kpc. CB54 belongs to the latter. Based on these results, we consider the reason for the random polarization map that we have observed for CB54. We find that the foreground is characterized by low polarization ($P \lesssim 0.5$ per cent) and a magnetic field parallel to the Galactic plane. The extended layer shows high polarization (P up to 5–7 per cent). We suggest that the field in this layer is nearly perpendicular to the Galactic plane and both layers are essentially inhomogeneous. This allows us to explain the randomness of polarization vectors around CB54 generally. The data – primarily observed by us in this work for CB54, by A. K. Sen and colleagues in previous works for three dark clouds CB3, CB25 and CB39, and by other authors for a region including the B1 cloud – are analysed to explore any correlation between polarization, the near-infrared, E(J − H), and optical, E(B − V), excesses, and the distance to the background stars. If polarization and extinction are caused by the same set of dust particles, we should expect good correlations. However, we find that, for all the clouds, the correlations are not strong.

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SiO as a chemical signature of outflows from bright, compact sources in MSX IR-dark clouds

Canadian Journal of Chemistry ◽

10.1139/v04-078 ◽

2004 ◽

Vol 82 (6) ◽

pp. 740-743 ◽

Cited By ~ 1

Author(s):

P A Feldman ◽

R O Redman ◽

L W Avery ◽

J Di Francesco ◽

J D Fiege ◽

...

Keyword(s):

Star Formation ◽

Young Stellar Objects ◽

Line Profiles ◽

Bipolar Outflows ◽

Dark Cloud ◽

Stellar Objects ◽

Dark Clouds ◽

Dense Cores ◽

Infrared Dark Clouds ◽

Compact Sources

The line profiles of dense cores in infrared-dark clouds indicate the presence of young stellar objects (YSOs), but the youth of the YSOs and the large distances to the clouds make it difficult to distinguish the outflows that normally accompany star formation from turbulence within the cloud. We report here the first unambiguous identification of a bipolar outflow from a young stellar object (YSO) in an infrared-dark cloud, using observations of SiO to distinguish the relatively small amounts of gas in the outflow from the rest of the ambient cloud. Key words: infrared-dark clouds, star formation, bipolar outflows, SiO, G81.56+0.10.

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Mapping the 13CO/C18O abundance ratio in the massive star-forming region G29.96−0.02

Astronomy and Astrophysics ◽

10.1051/0004-6361/201833658 ◽

2018 ◽

Vol 617 ◽

pp. A14 ◽

Cited By ~ 3

Author(s):

S. Paron ◽

M. B. Areal ◽

M. E. Ortega

Keyword(s):

Molecular Clouds ◽

Abundance Ratio ◽

High Mass ◽

Local Thermal Equilibrium ◽

Mass Star ◽

Galactocentric Distance ◽

Star Forming ◽

Physical Conditions ◽

The Galaxy ◽

Molecular Abundances

Aims. Estimating molecular abundances ratios from directly measuring the emission of the molecules toward a variety of interstellar environments is indeed very useful to advance our understanding of the chemical evolution of the Galaxy, and hence of the physical processes related to the chemistry. It is necessary to increase the sample of molecular clouds, located at different distances, in which the behavior of molecular abundance ratios, such as the 13CO/C18O ratio, is studied in detail. Methods. We selected the well-studied high-mass star-forming region G29.96−0.02, located at a distance of about 6.2 kpc, which is an ideal laboratory to perform this type of study. To study the 13CO/C18O abundance ratio (X13∕18) toward this region, we used 12CO J = 3–2 data obtained from the CO High-Resolution Survey, 13CO and C18O J = 3–2 data from the 13CO/C18O (J = 3–2) Heterodyne Inner Milky Way Plane Survey, and 13CO and C18O J = 2–1 data retrieved from the CDS database that were observed with the IRAM 30 m telescope. The distribution of column densities and X13∕18 throughout the extension of the analyzed molecular cloud was studied based on local thermal equilibrium (LTE) and non-LTE methods. Results. Values of X13∕18 between 1.5 and 10.5, with an average of about 5, were found throughout the studied region, showing that in addition to the dependency of X13∕18 and the galactocentric distance, the local physical conditions may strongly affect this abundance ratio. We found that correlating the X13∕18 map with the location of the ionized gas and dark clouds allows us to suggest in which regions the far-UV radiation stalls in dense gaseous components, and in which regions it escapes and selectively photodissociates the C18O isotope. The non-LTE analysis shows that the molecular gas has very different physical conditions, not only spatially throughout the cloud, but also along the line of sight. This type of study may represent a tool for indirectly estimating (from molecular line observations) the degree of photodissociation in molecular clouds, which is indeed useful to study the chemistry in the interstellar medium.

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