Your search keyword '"Morata, O."' showing total 3 results

1. ALMA Observations of HCO+ and HCN Emission in the Massive Star-forming Region N55 of the Large Magellanic Cloud.

Author

J., Nayana A., N., Naslim, Onishi, T., Kemper, F., Tokuda, K., Madden, S. C., Morata, O., Nasri, S., and Galametz, M.

Subjects

LARGE magellanic cloud, LOCAL thermodynamic equilibrium, MOLECULAR clouds, STAR formation, MOLECULAR weights

Abstract

We present the results of high spatial resolution HCO+(1−0) and HCN(1−0) observations of the N55 south region (N55-S) in the Large Magellanic Cloud (LMC), obtained with the Atacama Large Millimeter/submillimeter Array (ALMA). N55-S is a relatively less extreme star-forming region of the LMC characterized by a low radiation field. We carried out a detailed analysis of the molecular emission to investigate the relation between dense molecular clumps and star formation in the quiescent environment of N55-S. We detect 10 molecular clumps with significant HCO+(1−0) emission and 8 with significant HCN(1−0) emission, and estimate the molecular clump masses by virial and local thermodynamic equilibrium analysis. All identified young stellar objects (YSOs) in N55-S are found to be near the HCO+ and HCN emission peaks showing the association of these clumps with recent star formation. The molecular clumps that have associated YSOs show relatively larger line widths and masses than those without YSOs. We compare the clump properties of N55-S with those of other giant molecular clouds (GMCs) in the LMC and find that N55-S clumps possess similar size but relatively lower line width and larger HCN/HCO+(1−0) flux ratio. These results can be attributed to the low radiation field in N55-S resulted by relatively low star formation activity compared to other active star-forming regions like 30 Doradus-10 and N159. The dense gas fraction of N55-S is ∼0.025, lower compared to other GMCs of the LMC supporting the low star formation efficiency of this region. [ABSTRACT FROM AUTHOR]

Published

2020

2. YOUNG STARLESS CORES EMBEDDED IN THE MAGNETICALLY DOMINATED PIPE NEBULABased on observations carried out with the IRAM 30 m telescope. IRAM is supported by INSU/CNRS (France), MPG (Germany), and IGN (Spain).

Author

Frau, P., Girart, J. M., Beltrán, M. T., Morata, O., Masqué, J. M., Busquet, G., Alves, F. O., Sánchez-Monge, Á., Estalella, R., and Franco, G. A. P.

Published

2010

3. YOUNG STARLESS CORES EMBEDDED IN THE MAGNETICALLY DOMINATED PIPE NEBULA. II. EXTENDED DATA SET.

Author

Frau, P., Girart, J. M., Beltrán, M. T., Padovani, M., Busquet, G., Morata, O., Masqué, J. M., Alves, F. O., Sánchez-Monge, Á, Franco, G. A. P., and Estalella, R.

Subjects

NEBULAE, STAR formation, MAGNETIC fields, INTERSTELLAR medium, MOLECULAR clouds

Abstract

The Pipe nebula is a massive, nearby, filamentary dark molecular cloud with a low star formation efficiency threaded by a uniform magnetic field perpendicular to its main axis. It harbors more than a hundred, mostly quiescent, very chemically young starless cores. The cloud is therefore a good laboratory to study the earliest stages of the star formation process. We aim to investigate the primordial conditions and the relation among physical, chemical, and magnetic properties in the evolution of low-mass starless cores. We used the IRAM 30 m telescope to map the 1.2 mm dust continuum emission of five new starless cores, which are in good agreement with previous visual extinction maps. For the sample of nine cores, which includes the four cores studied in a previous work, we derived an AV to factor of (1.27 ± 0.12) × 10–21 mag cm2 and a background visual extinction of ∼6.7 mag possibly arising from the cloud material. We derived an average core diameter of ∼0.08 pc, density of ∼105 cm–3, and mass of ∼1.7 M☼. Several trends seem to exist related to increasing core density: (1) the diameter seems to shrink, (2) the mass seems to increase, and (3) the chemistry tends to be richer. No correlation is found between the direction of the surrounding diffuse medium magnetic field and the projected orientation of the cores, suggesting that large-scale magnetic fields seem to play a secondary role in shaping the cores. We also used the IRAM 30 m telescope to extend the previous molecular survey at 1 and 3 mm of early- and late-time molecules toward the same five new Pipe nebula starless cores, and analyzed the normalized intensities of the detected molecular transitions. We confirmed the chemical differentiation toward the sample and increased the number of molecular transitions of the “diffuse” (e.g., the “ubiquitous” CO, C2H, and CS), “oxo-sulfurated” (e.g., SO and CH3OH), and “deuterated” (e.g., N2H+, CN, and HCN) starless core groups. The chemically defined core groups seem to be related to different evolutionary stages: “diffuse” cores present the cloud chemistry and are less dense, while “deuterated” cores are the densest and present a chemistry typical of evolved dense cores. “Oxo-sulfurated” cores might be in a transitional stage exhibiting intermediate properties and a very characteristic chemistry. [ABSTRACT FROM AUTHOR]

Published

2012