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Starbursts Triggered by Cloud Compression in Interacting Galaxies

Published online by Cambridge University Press:  25 May 2016

Chanda J. Jog
Chanda J. Jog*
Affiliation:
Department of Physics, Indian Institute of Science, Bangalore 560012, India

Abstract

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We propose a physical mechanism for the triggering of starbursts in interacting spiral galaxies by shock compression of the pre-existing disk giant molecular clouds (GMCs). We show that as a disk GMC tumbles into the central region of a galaxy following a galactic tidal encounter, it undergoes a radiative shock compression by the pre-existing high pressure of the central molecular intercloud medium. The shocked outer shell of a GMC becomes gravitationally unstable, which results in a burst of star formation in the initially stable GMC. In the case of colliding galaxies with physical overlap such as Arp 244, the cloud compression is shown to occur due to the hot, high-pressure remnant gas resulting from the collisions of atomic hydrogen gas clouds from the two galaxies. The resulting values of infrared luminosity agree with observations. The main mode of triggered star formation is via clusters of stars, thus we can naturally explain the formation of young, luminous star clusters observed in starburst galaxies.

Type
Starbursts
Information
Symposium - International Astronomical Union , Volume 186: Galaxy Interactions at High and Low Redshift , 1999 , pp. 235 - 242
Copyright
Copyright © Kluwer 1999 

References

Aalto, S., Booth, R.S., Black, J.H., Koribalski, B., & Wielebinski, R. 1994, A & A, 286, 365 Google Scholar
Abraham, R.G. 1997, these proceedings Google Scholar
Bally, J., Stark, A.A., Wilson, R.W., & Henkel, C. 1988, ApJ, 324, 223 Google Scholar
Das, M. & Jog, C.J. 1995, ApJ, 451, 167 CrossRefGoogle Scholar
Downes, D., Radford, S.J.E., Guilloteau, S., Guelin, M., Greve, A., & Morris, D. 1992, A & A, 262, 424 Google Scholar
Downes, D., & Solomon, P.M. 1997, to appear in ApJ Google Scholar
Ho, L.C., & Filippenko, A.V. 1996, ApJ, 472, 600 CrossRefGoogle Scholar
Jog, C.J. 1995, BASI, 23, 135 Google Scholar
Jog, C.J., & Das, M. 1992, ApJ, 400, 476 CrossRefGoogle Scholar
Jog, C.J., & Das, M. 1996, ApJ, 473, 797 CrossRefGoogle Scholar
Jog, C.J., & Solomon, P.M. 1992, ApJ, 387, 152 CrossRefGoogle Scholar
Larson, R.B. 1987, in Starbursts and Galaxy Evolution, eds. Thuan, T.X., Montmerle, T., & Trann Thanh Van, J., Edition Frontieres, Paris, 467 Google Scholar
Norman, C.A. 1992, in Massive Stars in Starbursts, eds. Leitherer, C., Heckman, T.M., Norman, C.A., & Walborn, N.R., Cambridge Univ. Press, Cambridge, 271 Google Scholar
Schweizer, F., Miller, B.W., Whitmore, B.C., & Fall, S.M. 1996, AJ, 112, 1839 Google Scholar
Valluri, M., & Jog, C.J. 1990, ApJ, 357, 367 CrossRefGoogle Scholar
Vigroux, L. 1997, these proceedings.Google Scholar
Whitmore, B.C., & Schweizer, F. 1995, AJ, 109, 960 Google Scholar