Hostname: page-component-78c5997874-94fs2 Total loading time: 0 Render date: 2024-11-10T17:28:10.328Z Has data issue: false hasContentIssue false
  • English
  • Français

Clouds, cores, and stars in the nearest molecular complexes

Published online by Cambridge University Press:  03 August 2017

P. C. Myers
P. C. Myers*
Affiliation:
Harvard-Smithsonian Center for Astrophysics, 60 Garden Street, Cambridge, MA 02188, USA E-mail MYERS@CFA.BITNET

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

The properties and structure of six molecular complexes within 500 pc of the Sun are described and compared. They are generally organized into elongated filaments which appear connected to less elongated, more massive clouds. Their prominent star clusters tend to be located in the massive clouds rather than in the filaments. The complexes have similar structure, but big differences in scale, from a few pc to some 30 pc. They show a pattern of regional virial equilibrium, where the massive, centrally located clouds are close to virial equilibrium, while the less massive filaments and other small clouds have too little mass to bind their observed internal motions. Complexes can be ranked according to increasing size, mass, core mass, and the mass and number of the associated stars: they range from Lupus to Taurus to Ophiuchus to Perseus to Orion B to Orion A. The cores in nearby complexes tend to have maps which are elongated, rather than round. The core size, velocity dispersion, and column density of most cores are consistent with virial equilibrium. Cores in Orion tend to exceed cores in Taurus in their line width, size, temperature, mass, and in the mass of the associated star, if any. Stars in Orion tend to be more numerous and more massive than in Taurus, while those in Taurus tend to be more numerous and more massive than in Lupus. The mass of a core tends to increase with the mass of the cloud where it is found, with the mass of the star cluster with which it is associated, and with its proximity to a star cluster. These properties suggest that complexes and their constituent cores and clusters develop together over time, perhaps according to the depth of the gravitational well of the complex.

Keywords

star formationmolecular clouds
Type
Small Scale Structure
Information
Symposium - International Astronomical Union , Volume 147: Fragmentation of Molecular Clouds and Star Formation , 1991 , pp. 221 - 228
Copyright
Copyright © Kluwer 1991 

References

Bachiller, R., Cernicharo, J., and Duvert, G. 1985, “The Taurus-Auriga-Perseus Complex of Dark Clouds.” Astron. Astrophys. (Suppl.), 149, 273282.Google Scholar
Bachiller, R., Menten, K. M., and del Rio-Alvarez, S. 1990, “Anatomy of a Dark Cloud: a Multimolecular Study of Barnard 1.” Astron. Astrophys., in press.Google Scholar
Batrla, W., Wilson, T. L., Bastien, P., and Ruf, K. 1983, “Clumping in Molecular Clouds. The Region Between OMC1 and 2.” Astron. Astrophys., 128, 279290.Google Scholar
Beichman, C. A., Myers, P. C., Emerson, J., Harris, S., Mathieu, R.D., Benson, P. J., and Jennings, R. 1986, “Candidate Solar-Type Protostars in Nearby Molecular Cloud Cores.” Ap. J., 307, 337349.Google Scholar
Benson, P. J., and Myers, P. C. 1989, “A Survey for Dense Cores in Dark Clouds,” Ap. J. (Suppl.), 71, 89108.CrossRefGoogle Scholar
Cohen, M., and Kuhi, L. V. 1979, “Observational Studies of Pre-Main Sequence Evolution.” Ap. J. (Suppl.), 41, 743843.Google Scholar
Fuller, G. A. 1989, Molecular Studies of Dense Cores, Ph. D. thesis, Astronomy Department, U. of California, Berkeley.Google Scholar
Greenberg, M. A. 1988, Dense Cores and Star Formation in the Molecular Clouds L1506 and L1529, Senior Thesis, Department of Astronomy, Harvard University.Google Scholar
Harju, J., Walmsley, C. M., and Wouterlout, J. G. A. 1990, “Young Ammonia Clumps in the Orion Molecular Cloud.” Astron. Astrophys., in press.Google Scholar
Herbig, G. H. 1962, “The Properties and Problems of T Tauri Stars and Related Objects.” Adv. Astr. Ap., 1, 47101.Google Scholar
Herbig, G. H., and Bell, K. R. 1988, “Third Catalog of Emission-Line Stars of the Orion Population.” Lick Obs. Bull., No. 1111.Google Scholar
Ho, P. T. P., and Barrett, A. H. 1980, “Observations of Herbig-Haro Objects and Their Surrounding Dark Clouds.” Ap. J., 237, 3854.Google Scholar
Ho, P. T. P., Martin, R. M., Myers, P. C., and Barrett, A. H. 1977, “Gas Temperatures and Motion in the Taurus Dark Cloud.” Ap. J. (Letters), 215, L29L33.Google Scholar
Jones, B. F., and Herbig, G. H. 1979, “Proper Motions of T Tauri Variables and Other Stars Associated with The Taurus-Auriga Dark Clouds.” A. J., 84, 18721889.CrossRefGoogle Scholar
Krautter, J. 1990, “The Star Forming Region in Lupus.” preprint of paper presented at ESO Workshop on Low Mass Star Formation and Pre-Main-Sequence Objects, Garching, 1989.Google Scholar
Lada, E. 1990, Global Star Formation in the L1680 Molecular Cloud, Ph. D. thesis, Astronomy Department, University of Texas at Austin.Google Scholar
Larson, R. B. 1981, “Turbulence and Star Formation in Molecular Clouds.” MNRAS, 194, 809826.CrossRefGoogle Scholar
Loren, R. B. 1989a, “The Cobwebs of Ophiuchus I. Strands of 13CO: The Mass Distribution.” Ap. J., 338, 902924.CrossRefGoogle Scholar
Loren, R. B. 1989b, “The Cobwebs of Ophiuchus II. 13CO Filament Kinematics.” Ap. J., 338, 925944.Google Scholar
Loren, R. B., Wootten, H. A., and Wilking, B. A. 1990, “Cold DCO+ Cores and Protostar-Like Inclusions in the Warm ρ Ophiuchi Clouds.” Ap. J., in press.Google Scholar
Maddalena, R. J., and Thaddeus, P. 1986, “The Large System of Molecular Clouds in Orion and Monoceros.” Ap. J., 303, 375391.Google Scholar
McCaughrean, M. J. 1989, “Multicolour Near Infrared Imaging of the Orion Nebula and Trapezium Cluster.” B.A.A.S., 21, 712.Google Scholar
Murphy, D. C., Cohen, R., and May, J. 1986, “CO Observations of Dark Clouds in Lupus.” Astron. Astrophys., 167, 234238.Google Scholar
Myers, P. C., and Benson, P. J. 1983, “Dense Cores in Dark Clouds. II. NH3 Observations and Star Formation.” Ap. J., 266, 309320.CrossRefGoogle Scholar
Myers, P. C., Fuller, G. A., Goodman, A. A., and Benson, P. J. 1991, “Dense Cores in Dark Clouds. VI. Shapes.” submitted to Ap. J. CrossRefGoogle Scholar
Schwartz, R. D. 1977, “A Survey of Southern Dark Clouds for Herbig-Haro Objects and H-Alpha Emission Stars.” Ap. J. (Suppl.), 35, 161170.Google Scholar
Strom, K. M., Margulis, M., and Strom, S. E. 1989, “A Study of The Stellar Popolation in the Lynds 1641 Dark Cloud: Deep Near-Infrared Imaging.” Ap. J. (Letters), 345, L79L82.Google Scholar
Strom, K. M., Vrba, F. J., and Strom, S. E. 1976, “Infrared Surveys of Dark Cloud Complexes. H. The NGC 1333 Region.” A. J., 81, 314316.Google Scholar
Ungerechts, H., and Thaddeus, P. 1987, “A CO Survey of the Dark Nebulae in Perseus, Taurus, and Auriga.” Ap. J. (Suppl.), 63, 645690.Google Scholar
Wilking, B. A., Lada, C. J., and Young, E. T. 1989, IRAS Observations of the ρ Ophiuchi Infrared Cluster: Spectral Energy Distributions and Luminosity Function.” Ap. J., 340, 823852.Google Scholar