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A Model of Gas Recycling Based on Condensed H2

Published online by Cambridge University Press:  26 May 2016

Daniel Pfenniger*
Affiliation:
University of Geneva, Geneva Observatory, Switzerland

Abstract

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To address, among other questions, puzzling observations about star forming in the extreme outer HI disk of M31 (Cuillandre et al. 2001), a scenario of interstellar gas cycling between the visible and a very cold invisible phase is investigated. The key new element sketched here, allowing to maintain the bulk of the gas out of sight, is that molecular hydrogen becomes liquid or solid below 33 K at sufficiently high pressure, allowing AU-sized spheres of very cold gas to be stabilised by incompressible cores of condensed H2 (Pfenniger 2004). These predicted cold gas globules are relatively weakly bound (~ 10−3eV/nucleon), such that their lifetime depends directly on the ambient UV/CR excitation level. At galactic scale the globules behave as collisionless bodies, and evaporate and become the usual visible ISM gas through heating. Much of the ISM gas can thus spend a long time in this cold condensed phase in low excitation regions. N-body simulations of galactic disks modeling such effects have been run, and some of their features are described in more detail in this volume and elsewhere (Revaz & Pfenniger 2004).

Type
Part 2. Origin
Copyright
Copyright © Astronomical Society of the Pacific 2004 

References

Bosma, A. 1981, AJ, 86, 1791.Google Scholar
Bureau, M., et al. 1999, AJ, 118, 2158.CrossRefGoogle Scholar
Charmandaris, V., Combes, F., & van der Hulst, J.M. 2000, A&A, 356, 1.Google Scholar
Combes, F., & Pfenniger, D. 1997, A&A, 327, 453.Google Scholar
Cuillandre, J.-Ch, et al. 2001, ApJ, 554, 190.Google Scholar
Draine, B. T. 2004, in “The Cold Universe”, Saas Fee Advanced Course 32, Pfenniger, D. & Revaz, Y. (eds.), Springer-Verlag, Berlin, p. 213.Google Scholar
Hoekstra, H., van Albada, T. S., & Sancisi, R. 2001, MNRAS, 323, 453.Google Scholar
Huber, D., & Pfenniger, D. 2002 A&A, 386, 359.Google Scholar
Klessen, R.S., Heitsch, F., & Mac Low, M.-M. 2000, ApJ, 535, 887.Google Scholar
Larson, R.B. 1969, MNRAS, 145, 271.Google Scholar
Masset, F. S., & Bureau, M. 2003, ApJ, 586, 152.Google Scholar
Padmanabhan, T. 2001, Theoretical Astrophysics Vol. II, Cambridge.CrossRefGoogle Scholar
Pfenniger, D. 2004, A&A, to be submitted.Google Scholar
Pfenniger, D., & Combes, F. 1994, A&A, 285, 93 (PC94).Google Scholar
Revaz, Y., & Pfenniger, D. 2004, A&A, to be submitted.Google Scholar
Schwarz, M. P. 1981, ApJ, 247, 77.Google Scholar
Smith, D.A., et al. 2000, ApJ, 538, 608.Google Scholar